TW201637347A - Electromotive force magnetic energy conversion device - Google Patents

Abstract

This invention relates to an electromotive force magnetic energy conversion device. Magnetic flux outside a magnet set is parallel to a movement direction of the magnet set. No magnetic resistance is produced in a coil. By means of a sensing control circuit, the coil induces to produce magnetic force that is advantageous in the movement direction of the magnet set. Same-pole opposite magnet modules are employed to cancel vertical magnetic forces, which reinforces horizontal magnetic forces advantageous in the movement direction of the magnet set, thus generating and increasing a forward magnet-assistant force corresponding to the movement direction of the magnet set, and resulting in the electromotive force and magnetic energy conversion device that greatly improves energy conversion rate.

Description

Electromotive force magnetic energy conversion device

The invention belongs to the technical field of an electric motor, in particular to an electromotive force magnetic energy conversion device capable of improving energy conversion rate, thereby avoiding magnetic resistance, reducing energy consumption, and extracting horizontal magnetic thrust having a direction of movement of the magnetic group. Motor device for the purpose of improving energy conversion rate.

In general, the motor is composed of two magnets that are in relative motion. As disclosed in FIG. 1, the two magnets can be respectively defined as a magnetic group (10) as a stator and a moving magnet (20) as a rotor. The magnetic group (10) is formed by a series of adjacent first magnetic members (11) and second magnetic members (12), and adjacent first and second magnetic members (11, 12) are upper and lower. The magnetic poles at the ends are in a different shape, and the moving magnets (20) are displaceable.

Since the magnetic lines of force of the first and second magnetic members (11, 12) are most dense near the center line of the magnet, the outer magnetic flux NR is on the right side of the magnet center line, with the N-pole magnetic pole of the magnet middle line of the first magnetic member (11). There is an external magnetic flux NL on the left side of the magnet neutral line; similarly, in the S pole magnetic pole of the magnet middle line of the second magnetic member (12), there is an external magnetic current SR on the right side of the magnet neutral line, and an external magnetic current SL on the left side of the magnet neutral line. Wherein NR and NL are in the opposite direction of outward expansion, while SR and SL are in the opposite direction of inward convergence.

In actual operation, when the moving magnetic member (20) is located on the left side of the magnet neutral line (N pole) of the first magnetic member (11), the two will be outside the first magnetic member (11). The magnetic current NL generates a reverse force corresponding to the forward movement of the moving magnetic member (20) (as shown in the first figure), and when the moving magnetic member (20) passes over the magnet center line of the first magnetic member (11), The reverse magnetic force corresponding to the forward movement of the moving magnetic member (20) is generated by the external magnetic current NR of the first magnetic member (11) (as shown in the second figure), and when the moving magnetic member (20) is located at the second magnetic field. When the magnet center line (S pole) of the piece (12) is on the left side, the two will generate a cis suction force corresponding to the forward movement of the moving magnetic piece (20) due to the external magnetic current SL of the second magnetic piece (12) (such as the third figure). As shown in the figure), when the moving magnet (20) passes over the magnet center line of the second magnetic member (12), the two will generate a corresponding moving magnetic member due to the external magnetic current SR of the second magnetic member (12) ( 20) The forward thrust of the forward motion (as shown in the fourth figure), so that the moving magnetic component (20) continuously experiences the interaction of four physical phenomena such as reverse blocking force, reverse pulling force, cis suction force and forward thrust during the displacement process. Force; the forward and forward thrust of the above four physical forces can cause the magnetic component (20) to generate magnetic assistance that is favorable for inertial acceleration, while the reverse and reverse tensions cause the magnetic component (20) to be disadvantageous. The magnetic reactance of inertial acceleration is also in energy Under the laws of constant anti-energy proliferation resistance of the key players, causing loss of kinetic energy, affect the energy conversion rate.

As mentioned above, since the conventional motor is basically composed of a group of relatively moving magnets and coils, the coil is practically magnetic due to the current generation, because the external magnetic lines of the magnet have phase changes, and the magnetic lines cannot be It is difficult to cover each other, so when the two magnets interact, the result of the interaction of an infinite number of magnetic lines with a phase change of 360 degrees will simultaneously produce an infinite number of magnetic moment combinations of magnetic repulsion and magnetic attraction, that is, It is said that the force and the reaction force are both generated and cannot be avoided. However, there is no way to solve this problem in the existing motor technology. No matter the advanced technology such as excitation or switch electronic control circuit, it can only be reduced. The resistance of the reaction force, but can not eradicate the reaction force, can only generalize the bearing, in other words, if it can effectively avoid the magnetic resistance that is not conducive to the acceleration of inertia, it can produce the effect of small energy consumption and large kinetic energy, so how to achieve this goal, The industry is waiting for developers.

The reason is that the inventors have in-depth discussion on the problems faced by the above-mentioned existing electric motors, and have actively pursued solutions through years of research and development experience in related industries, and have been successfully developed through continuous efforts in research and trials. An electromotive force magnetic energy conversion device is provided to overcome the inconvenience and trouble caused by the magnetic resistance of the existing motor.

Therefore, the main object of the present invention is to provide an electromotive force magnetic energy conversion device capable of improving the performance of a motor, thereby avoiding magnetic resistance, accelerating magnetic assistance, and simultaneously applying the same pole opposite magnetic module to reduce kinetic energy loss, thereby improving energy conversion. Efficiency, further achieve the effect of small energy consumption and large kinetic energy.

Based on the above, the present invention mainly achieves the foregoing objects and effects by the following technical means, which are composed of a homopolar magnetic module, at least one coil and at least one inductive control circuit; The magnetic module has at least two magnetic groups that are opposite to each other and are arranged in parallel, and the equivalent pole opposite magnetic module can synchronously move relative to the coil, and the magnetic groups are respectively driven by the external magnetic current and the moving direction. a parallel magnet; the coils are parallel to the direction of movement of the magnetic group and are disposed between the two magnetic groups of the same-pole magnetic module, and are equally spaced from the two magnetic groups, and the coils are Connected to the inductive control circuit; as such, the inductive control circuit is a forward switching circuit and a The reverse switching circuit is composed of the forward and reverse switching circuits synchronously connecting the coils; thereby, since the magnetic current outside the magnetic group is parallel to the moving direction, the coil has no proliferative magnetic resistance, and when the coil middle line respectively corresponds to the magnetic pole center line of the magnetic group or When the magnet is in the middle line, the switch of the induction control circuit can be turned on or off, so that the coil induces the magnetic assistance of the magnetic group in the direction of movement, and the vertical magnetic force can be offset by the same-pole magnetic module. The horizontal magnetic force of the direction of the magnetic flux group can further reduce the added value and improve the economic efficiency of the motor by achieving small energy consumption and large kinetic energy.

Among them, the same-pole magnetic module can solve the problem that the external magnetic lines have opposite phase changes, and the vertical force stress balance can solve the problem that the magnetic lines outside the magnetizing coil are reversed.

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

(10) ‧‧‧Magnetic Group

(11)‧‧‧First magnetic parts

(12)‧‧‧Second magnetic parts

(20) ‧‧‧Magnetic parts

(5) ‧‧‧The same pole opposite magnetic module

(50) ‧‧‧Magnetic Group

(51)‧‧‧First magnetic parts

(52)‧‧‧Second magnetic parts

(65)‧‧‧ coil

(7)‧‧‧Induction control circuit

(70)‧‧‧ Forward switching circuit

(71)‧‧‧Power

(721)‧‧‧First Diode

(722)‧‧‧Secondary diode

(73)‧‧‧First switch

(74)‧‧‧Second switch

(75)‧‧‧Reverse switch circuit

(771)‧‧‧ Third Dipole

(772)‧‧‧4th Diode

(78)‧‧‧Third switch

(79)‧‧‧fourth switch

X‧‧‧Magnetic center line

Y‧‧‧Magnetic center line

Z‧‧‧Magnetic center line

The first figure is a schematic diagram showing the reverse force of the corresponding forward motion direction under the relative motion of the two magnets.

The second figure is a schematic diagram of the reverse pulling force corresponding to the direction of forward motion under the relative motion of the two magnets.

The third figure is a schematic diagram of the cis-suction force corresponding to the direction of forward motion under the relative motion of the two magnets.

The fourth figure is a schematic diagram of the forward thrust corresponding to the direction of forward motion caused by the relative motion of the two magnets.

Figure 5 is a schematic view showing the structure of an embodiment of the electromotive force magnetic energy conversion device of the present invention for explaining the relative relationship of the components.

Fig. 6 is a schematic view showing the magnetic lines of the same-pole magnetic module and the coil in the electromotive force magnetic energy conversion device of the present invention.

Seventh and eighth figures are diagrams showing the operation of the embodiment in which the electromotive force mode is positively energized in the first half of the first magnetic member and the magnetic pole is displaced from the S pole to the N pole.

Ninth and tenth drawings: The operation diagram of the embodiment in which the electromotive force mode is positively energized in the second half of the first magnetic member, and the magnetic pole is displaced from the S pole to the N pole.

The eleventh and twelfth drawings are diagrams showing the operation of the embodiment in which the electromotive force mode is reversely supplied to the first half of the second magnetic member, and the magnetic pole is displaced from the N pole to the S pole.

The thirteenth and fourteenth drawings are diagrams showing the operation of the embodiment in which the electromotive force mode is reversely supplied to the second half of the second magnetic member, and the magnetic pole is displaced from the N pole to the S pole.

The present invention is an electromotive force magnetic energy conversion device, with reference to the specific embodiments of the present invention and its components, 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 references, It is merely for convenience of description, not limiting the invention, nor limiting 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 electromotive force magnetic energy conversion device of the present invention is constituted by a same pole opposite magnetic module (5), at least one coil (65) and at least one inductive control circuit (7) as shown in the fifth and sixth figures. Composed, and the same pole opposite magnetic module (5) and relative to the coil (65) to produce relative rotation or linear motion, and the induction control circuit (7) for the steering coil (65) and the power supply (71) And the input direction; and the detailed configuration of the embodiment of the electromotive force magnetic energy conversion device, please refer to the figure shown in the fifth figure, wherein the fifth figure is a brief architecture and corresponding relationship of the embodiment of the present invention, and the sixth figure is The magnetic lines and magnetic forces of the same-pole magnetic module (5) and the coil (65) are revealed, and the same-pole magnetic module (5) is a magnetic group which is arranged by at least two sets of opposite poles and arranged in parallel. (50) Composition [The sixth figure discloses an embodiment of three sets of magnetic groups (50) and two sets of coils (65) aligned in parallel and parallel, for explaining the magnetic relationship between the opposite poles, In the other figures, the magnetic group (50) and the set of coils (65) which are arranged in two sets of opposite poles and are arranged in parallel are an embodiment of the present invention. The two magnetic groups (50) are synchronously movable relative to the coil (65), and the two magnetic groups (50) are respectively at least one first magnetic member (51) and at least one second magnetic member (52) whose magnetic poles are parallel to the moving direction. Arranged adjacent to each other, and the opposite ends of the first and second magnetic members (51, 52) adjacent to each other are arranged opposite to each other, that is, the S pole of the first magnetic member (51) corresponds to the second The S pole magnetic pole of the magnetic member (52), the N pole magnetic pole of the first magnetic member (51) correspond to the N pole magnetic pole of the second magnetic member (52), and the magnetic group of the same pole opposite magnetic module (5) ( 50) The magnetic pole center lines of the first and second magnetic members (51, 52) are respectively defined as X, Y, and the magnet middle line is defined as Z; and the coil (65) and the magnetic group (50) The moving direction is parallel and is disposed between the two magnetic groups (50) of the same-pole opposite magnetic module (5), and is equally spaced from the two magnetic groups (50), and the coil (65) is coupled to the sensing control circuit. (7) Parallel, for being controlled by the inductive control circuit (7) to form a synchronous action, and then the coil (65) is turned on to form a magnetic component with a magnetic pole, and the two ends of the coil (65) can be respectively defined as LL and LR The center of the coil (65) can be defined as LM, and the current direction of the coil (65) can be changed by the current direction of the coil (65), and the magnetic poles of the LL end and the LR end can be changed. As shown in the sixth figure, since the coil (65) is disposed between the two magnetic groups (50) of the same-pole magnetic module (5) and is equidistant from the two magnetic groups (50), The vertical magnetic force of the two magnetic groups (50) and the coil (65) are mutually abutted, and the horizontal magnetic force is added, and the same-pole magnetic modules (5) are arranged in a repulsive manner opposite to the same pole. The external magnetic flow rotation angle can be changed, and the magnetic field expansion phenomenon of the magnetic group (50) can be corrected, so that the magnetic flux lines in the magnetic channel are uniform and full, and a certain magnetic current is formed. Therefore, the magnetic flux between the two magnetic groups (50) of the opposite pole magnetic module (5) forms a directional magnetic current, and the opposite poles of the same pole opposite magnetic module (5) are aligned, which can offset two The vertical magnetic force of the magnetic group (50) relative to the coil (65), and the horizontal magnetic force of the two magnetic groups (50) relative to the coil (65), can enhance the force in the forward direction, and contribute to the generation The magnetic assisting force of the moving direction; as described, the sensing control circuit (7) is composed of a forward switching circuit (70) and a reverse switching circuit (75), and the forward and reverse switching circuits (70, 75) are synchronized. Connecting a coil (65), wherein the forward switching circuit (70) has a power source (71), and the positive pole of the power source (71) is connected to the coil (65) through a first diode (721) of a guiding coil (65) A first switch (73) is connected in series between the first diode (721) and the coil (65), and a second switch (74) is coupled between the first switch (73) and the coil (65). The other end of the second switch (74) is connected to the second diode (722) of a guiding power source (71). Source (71) negative electrode. The reverse switching circuit (75) has a power supply (71), and the negative electrode of the power supply (71) is connected to the coil (65) through a third diode (771) of a guiding power source (71), and the third diode A third switch (78) is connected in series between the body (771) and the coil (65), and a fourth switch (79) is further connected between the third switch (78) and the coil (65). The fourth switch (79) The other end is connected to the positive terminal of the power source (71) through a fourth diode (772) of a guiding coil (65). Furthermore, the positive and negative switching circuits (70, 75) of the inductive control circuit (7) can detect the coil (65) center line [LM] corresponding to the magnetic pole center lines of the first and second magnetic parts (51, 52), respectively. When the X, Y or the magnet center line Z is generated, an action signal for controlling whether the first to fourth switches (73, 74, 78 or 79) are turned on or not is generated; thereby, the group composition can effectively avoid the magnetic resistance force and the magnetic flux assisting force. The electromagnetism energy conversion device that uses the same pole opposite magnetic module to help the horizontal magnetic thrust of the magnetic group moving direction can reduce the kinetic energy loss and improve the energy conversion rate.

When the two magnetic groups (50) of the same pole opposite magnetic module (5) are synchronously displaced relative to the coil (65), the first and second magnetic members (51, 52) of the magnetic group (50) are passed through When a magnetic coil (65) is generated, magnetic forces such as blocking, pulling, sucking, and pushing are generated in a relative order, and the suction and pushing are such that the moving homopolar magnetic module (5) is favorable for inertia. Accelerated magnetic assist, while the blocking and pulling will cause the moving homopolar magnetic module (5) to generate magnetic resistance that is not conducive to inertial acceleration, so the magnetic flux and direction of motion of the magnetic group (50) of the present invention can be transmitted. The forward and reverse switching circuits (70, 75) of the parallel and inductive control circuit (7) are used to perform the inductive magnetic poles of the conversion coil (65) for avoiding the blocking and pulling force of the unfavorable moving direction, and the promotion of the motion direction is promoted. And magnetic absorption force to reduce kinetic energy loss and improve energy conversion rate; As for the electromotive force magnetic energy conversion device of the present invention, in actual use, as shown in the seventh figure, when the displacement of the magnetic group (50) of the same-pole opposite magnetic module (5) is shifted by the S pole of the second magnetic member (52) When the S pole of the first magnetic member (51) and the magnetic center line X correspond to the center [LM] of the coil (65), the induction control circuit (7) can actuate the forward switching circuit (70) after detection. The first switch (73) is turned on, and the second switch (74) and the third and fourth switches (78, 79) of the reverse switch circuit (75) are both open, so that the forward switch circuit (70) The current in the power source (71) can enter the coil (65) through the first diode (721), and the first half of the first magnetic component forming the electromotive force is positively energized, and the coil (65) is excited to form a magnetic component. Moreover, the LL of the coil (65) is S pole and LR is N pole. When the same pole opposite magnetic module (5) is continuously displaced, as shown in the eighth figure, since the magnetic lines of the first magnetic member (51) of the magnetic group (50) flow from the N pole to the S pole, and the coil (65) The magnetic lines of force flow from the N pole to the S pole in the same direction, and the two magnetic groups (50) of the same pole opposite magnetic module (5) have a perpendicular magnetic force against the coil (65), and the horizontal magnetic The forces are added to each other to form a forward thrust corresponding to the direction of movement of the magnetic group (50), so that the same-pole magnetic module (5) can enhance the force that contributes to the direction of motion under the inertial force.

Next, as shown in the ninth figure, when the displaced magnetic group (50) of the same pole opposite magnetic module (5) is moved from the S pole of the first magnetic member (51) to the N of the first magnetic member (51) When the magnet center line Z of the first magnetic member (51) corresponds to the center [LM] of the coil (65), the sensing control circuit (7) can actuate the forward switching circuit (70) after detecting The third and fourth switches (78, 79) of a switch (73) and the reverse switch circuit (75) form a disconnected state, and the second switch (74) is turned on, so that the power source (71) can pass through the second diode. (722) The coil (65) is connected, and the LL of the coil (65) is N pole and LR is S pole. Such continuous displacement of the opposite pole magnetic module (5) At the same time, as shown in the tenth figure, the magnetic lines of the first magnetic member (51) of the magnetic groups (50) of the same pole opposite magnetic module (5) flow from the N pole to the S pole, and the coil (65) The magnetic lines of force flow from the N pole to the S pole to the opposite direction, and the two magnetic groups (50) of the same pole opposite magnetic module (5) are perpendicular to the coil (65), and the horizontal magnetic force acts. The force is added to form a forward suction force corresponding to the moving direction of the magnetic group (50), so the same-pole magnetic module (5) can enhance the force that contributes to the moving direction under the inertial force.

Furthermore, as shown in the eleventh figure, when the magnetic group (50) of the displaced pole-opposing magnetic module (5) is moved from the N pole of the first magnetic member (51) to the second magnetic member (52) When the N pole and the magnetic pole center line Y correspond to the center [LM] of the coil (65), the sensing control circuit (7) can actuate the third switch (78) of the reverse switching circuit (75) to be turned on after detection. And the first switch and the second switch (79) of the fourth switch (79) and the forward switch circuit (70) form a disconnected state, so that the power source (71) can be connected to the coil via the third diode (771) ( 65), and the coil (65) is excited to form a magnetic member, so that the LL of the coil (65) is N pole and LR is S pole. When the same polarity opposite magnetic module (5) is continuously displaced, as shown in the twelfth figure, since the magnetic lines of the second magnetic member (52) of the magnetic group (50) flow from the N pole to the S pole, The magnetic lines of the coil (65) flow from the N pole to the S pole in the same direction, and the two magnetic groups (50) of the same pole opposite magnetic module (5) are perpendicular to the coil (65), and the horizontal magnetic force is opposite. The forces are added to form a forward thrust corresponding to the direction of motion of the magnetic group (50), so the same-opposing magnetic module (5) can enhance the force that contributes to the direction of motion under the inertial force.

Then, as shown in the thirteenth figure, when the magnetic group (50) of the displaced pole-opposing magnetic module (5) is moved from the N pole of the second magnetic member (52) to the second magnetic member (52) S pole, and the magnet center line Z of the second magnetic member (52) corresponds to the coil (65) In the central [LM], the sensing control circuit (7) can actuate the first switch of the first switch, the second switch (73, 74) and the reverse switch circuit (75) after the detection (7) ( 78) forming a broken circuit, and the fourth switch (79) of the reverse switching circuit (75) is turned on, so that the current in the power supply (71) of the reverse switching circuit (75) can pass through the fourth diode (772) The second half of the second magnetic member forming the electromotive force is reversely energized to enter the coil (65), and the LL of the coil (65) is S pole and LR is N pole. When the same polarity opposite magnetic module (5) is continuously displaced, as shown in FIG. 14, the second magnetic member (52) of the magnetic group (50) of the magnetic module (5) of the same pole opposite to the magnetic pole (5) The magnetic lines of force flow from the N pole to the S pole, and the magnetic lines of force from the coil (65) flow from the N pole to the S pole in the opposite direction, and the two magnetic groups (50) in the same pole opposite magnetic module (5) are opposite to the coil (65). The vertical magnetic force is opposite to each other, and the horizontal magnetic force is added to form a forward suction force corresponding to the moving direction of the magnetic group (50), so the same-pole magnetic module (5) can be enhanced under inertial force. The force that helps the direction of movement.

Through the continuous circulation of the seventh to fourteenth modes, the external magnetic current of the magnetic group (50) is parallel to the moving direction, the coil (65) has no proliferative magnetic resistance, and the positive and negative of the induction control circuit (7). Whether the first to fourth switches (73, 74, 78, 79) of the switch circuit (70, 75) are turned on or off, so that the coil (65) senses the magnetic assist force in the direction of movement of the magnetic group (50), forming push and suck The magnetic force, so as to avoid the reverse magnetic force which is not conducive to the direction of motion, the forward magnetic force which is favorable for the direction of motion, and at the same time can offset the vertical direction by the same pole opposite magnetic module (5) The magnetic force enhances the horizontal magnetic force of the magnetic group (50), and adds a forward magnetic force under the inertia of motion, which can reduce the internal dynamic loss and improve the energy conversion rate.

By this, it can be understood that the present invention is an excellent creation, except Effectively solve the problems faced by the practitioners, and greatly enhance the efficacy, and in the same technical field, the same or similar product creation or public use is not seen, and at the same time, the efficiency is improved, so the invention has met the invention patents. The requirements of "newness" and "progressiveness" are to apply for invention patents in accordance with the law.

(5) ‧‧‧The same pole opposite magnetic module

(50) ‧‧‧Magnetic Group

(51)‧‧‧First magnetic parts

(52)‧‧‧Second magnetic parts

(65)‧‧‧ coil

(7)‧‧‧Induction control circuit

(70)‧‧‧ Forward switching circuit

(71)‧‧‧Power

(721)‧‧‧First Diode

(722)‧‧‧Secondary diode

(73)‧‧‧First switch

(74)‧‧‧Second switch

(75)‧‧‧Reverse switch circuit

(771)‧‧‧ Third Dipole

(772)‧‧‧4th Diode

(78)‧‧‧Third switch

(79)‧‧‧fourth switch

X‧‧‧Magnetic center line

Y‧‧‧Magnetic center line

Z‧‧‧Magnetic center line

Claims (17)

An electromotive force magnetic energy conversion device is composed of a homopolar magnetic module, at least one coil and at least one inductive control circuit; the homopolar magnetic module has at least two magnets that are opposite to each other and are arranged in parallel And the equal pole opposite magnetic module can synchronously move relative to the coil, and the magnetic groups are respectively composed of magnets whose external magnetic current can be parallel to the moving direction; and the coils and the magnetic group moving direction Parallel and disposed between the two magnetic groups of the same pole opposite magnetic module, and equidistantly spaced from the two magnetic groups, and the coils are connected to the induction control circuit; thus, the sensing control circuits are The forward switching circuit and a reverse switching circuit are formed, and the forward and reverse switching circuits are synchronously connected to the coil. The electromotive force magnetic energy conversion device according to claim 1, wherein the magnetic groups are respectively arranged by adjacently spacing at least one first magnetic member and at least one second magnetic member having magnetic poles parallel to the moving direction, and The first and second magnetic members adjacent to each other are arranged in opposite directions of the same pole magnetic pole. The electromotive force magnetic energy conversion device according to claim 1, wherein the forward switching circuit of the inductive control circuit has a power source, and the positive electrode of the power supply is connected to the coil through a first diode of a guiding coil, and the first a first switch is connected in series between the diode and the coil, and a second switch is connected between the first switch and the coil, and the other end of the second switch is connected through a second diode of the guiding power source. The reverse polarity switch circuit has a power supply, the negative pole of the power supply is connected to the coil through a third diode of a guiding power source, and a third switch is connected in series with the third diode body and the third switch. Between the coil A fourth switch is connected to the other end, and the other end of the fourth switch is connected to the positive pole of the power supply through a fourth diode of a guiding coil. An electromotive force magnetic energy conversion device is composed of a homopolar magnetic module, at least one coil and at least one inductive control circuit; the homopolar magnetic module has at least two magnets that are opposite to each other and are arranged in parallel And the equal pole opposite magnetic module can synchronously move relative to the coil, and the magnetic groups are respectively composed of magnets whose external magnetic current can be parallel to the moving direction; and the coils and the magnetic group moving direction Parallel and disposed between the two magnetic groups of the same pole opposite magnetic module, and equidistantly spaced from the two magnetic groups, and the coils are connected to the induction control circuit; thus, the sensing control circuits are a forward switching circuit and a reverse switching circuit, wherein the positive and negative switching circuits are synchronously connected to the coil, wherein the forward switching circuit has a power supply, and the positive pole of the power supply is connected to the coil through a first diode of a guiding coil, and a first switch is connected in series between the first diode and the coil, and a second switch is connected between the first switch and the coil, and the other end of the second switch is transmitted through a second diode of a guiding power source. Connecting the negative pole of the power supply; the reverse switching circuit has a power supply, the negative pole of the power supply is connected to the coil through a third diode of a guiding power source, and a third switch is connected in series between the third diode and the coil, and A fourth switch is connected between the three switches and the coil, and the other end of the fourth switch is connected to the positive pole of the power supply through a fourth diode of a guiding coil. The electromotive force magnetic energy conversion device according to claim 4, wherein the magnetic groups are respectively at least one first magnetic member whose magnetic pole is parallel to the moving direction and At least one of the second magnetic members is arranged adjacent to each other, and the first and second magnetic members adjacent to each other are arranged in opposite directions of the same magnetic pole. An electromotive force magnetic energy conversion device is composed of a homopolar magnetic module, at least one coil and at least one inductive control circuit; the homopolar magnetic module has at least two magnets that are opposite to each other and are arranged in parallel And the equal pole opposite magnetic module can synchronously move relative to the coil, and the magnetic groups are respectively composed of magnets whose external magnetic current can be parallel to the moving direction; and the coils and the magnetic group moving direction Parallel and disposed between the two magnetic groups of the same pole opposite magnetic module, and equidistantly spaced from the two magnetic groups, and the coils are connected to the induction control circuit; thus, the sensing control circuits are a forward switching circuit, the forward switching circuit is connected to the coil, and the forward switching circuit has a power supply, the positive pole of the power supply is connected to the coil through a first diode of a guiding coil, and the first diode is coupled to the first diode A first switch is connected in series between the coils. The electromotive force magnetic energy conversion device according to claim 6, wherein the magnetic groups are respectively arranged by adjacently spacing at least one first magnetic member and at least one second magnetic member having magnetic poles parallel to the moving direction, and The first and second magnetic members adjacent to each other are arranged in opposite directions of the same pole magnetic pole. The electromotive force magnetic energy conversion device according to claim 6, wherein a second switch is connected between the first switch and the coil, and the other end of the second switch is connected through a second diode of the guiding power source. The power supply is negative. An electromotive force magnetic energy conversion device, which is composed of a homopolar magnetic module, at least one coil and at least one inductive control circuit; The same-pole magnetic module has at least two magnetic groups that are opposite to each other and are arranged in parallel, and the equivalent pole-opposing magnetic module can synchronously move relative to the coil, and the magnetic groups are respectively external magnetic The flow may be composed of magnets parallel to the direction of motion; and the coils are parallel to the direction of movement of the magnetic group and are disposed between the two magnetic groups of the same-pole magnetic module and are equally spaced from the two magnetic groups. And the coils are connected to the inductive control circuit; wherein the inductive control circuit is composed of a forward switching circuit, the forward switching circuit is connected to the coil, and the forward switching circuit has a power supply, and the negative pole of the power supply A second diode connected to the power source is connected to the coil, and a second switch is connected in series between the second diode and the coil. The electromotive force magnetic energy conversion device according to claim 9, wherein the magnetic groups are respectively arranged by adjacently spacing at least one first magnetic member and at least one second magnetic member parallel to the moving direction of the magnetic pole, and The first and second magnetic members adjacent to each other are arranged in opposite directions of the same pole magnetic pole. The electromotive force magnetic energy conversion device of claim 9, wherein a first switch is connected to the second switch and the coil, and the other end of the first switch is connected through the first diode of the guiding coil. The power supply is positive. An electromotive force magnetic energy conversion device is composed of a homopolar magnetic module, at least one coil and at least one inductive control circuit; the homopolar magnetic module has at least two magnets that are opposite to each other and are arranged in parallel And the equal pole opposite magnetic module can synchronously move relative to the coil, and the magnetic groups are respectively composed of magnets whose external magnetic current can be parallel to the moving direction; The coils are parallel to the direction of movement of the magnetic group and are disposed between the two magnetic groups of the same-pole opposite magnetic module, and are equally spaced from the two magnetic groups, and the coils are connected to the induction control circuit; The inductive control circuit is composed of a reverse switching circuit, the reverse switching circuit is connected to the coil, and the reverse switching circuit has a power supply, and the negative pole of the power supply is connected to the coil through a third diode of the guiding power source, and A third switch is connected in series between the third diode and the coil. The electromotive force magnetic energy conversion device according to claim 12, wherein the magnetic groups are respectively arranged by adjacently spacing at least one first magnetic member and at least one second magnetic member parallel to the moving direction of the magnetic pole, and The first and second magnetic members adjacent to each other are arranged in opposite directions of the same pole magnetic pole. The electromotive force magnetic energy conversion device of claim 12, wherein a fourth switch is coupled between the third switch and the coil, and the other end of the fourth switch is connected through a fourth diode of a guiding coil. The power supply is positive. An electromotive force magnetic energy conversion device is composed of a homopolar magnetic module, at least one coil and at least one inductive control circuit; the homopolar magnetic module has at least two magnets that are opposite to each other and are arranged in parallel And the equal pole opposite magnetic module can synchronously move relative to the coil, and the magnetic groups are respectively composed of magnets whose external magnetic current can be parallel to the moving direction; and the coils and the magnetic group moving direction Parallel and disposed between the two magnetic groups of the same pole opposite magnetic module, and equidistantly spaced from the two magnetic groups, and the coils are connected to the induction control circuit; The inductive control circuit is composed of a reverse switching circuit, the reverse switching circuit is connected to the coil, and the reverse switching circuit has a power supply, and the positive pole of the power supply is connected to the coil through a fourth diode of a guiding coil, and A fourth switch is connected in series between the fourth diode and the coil. The electromotive force magnetic energy conversion device according to claim 15, wherein the magnetic groups are respectively arranged by adjacently spacing at least one first magnetic member and at least one second magnetic member parallel to the moving direction of the magnetic pole, and The first and second magnetic members adjacent to each other are arranged in opposite directions of the same pole magnetic pole. The electromotive force magnetic energy conversion device of claim 15, wherein the fourth switch is coupled to the coil and is provided with a third switch, and the other end of the third switch is connected through a third diode of the guiding power source. The power supply is negative.