WO2018068162A1 - Full load power generation device - Google Patents

Abstract

A full load power generation device consists of at least one magnetic column group (10) and at least one sensing column group (20) which is movable with respect to the magnetic column group. The magnetic column group (10) has at least two magnetic parts (11, 12) of equal length which magnetize in the direction of movement, and there are magnetic gaps (15) of equal length between adjacent magnetic parts (11, 12). The adjacent portions of the adjacent magnetic parts (11, 12) have the same polarity. The sensing column groups (20) each have one or more coaxial sensing parts (21). The various sensing parts (21) each have a conducting magnet (22) and a coil (25) wound around the conducting magnet (22). Furthermore, the length of the coil (25) of each sensing part (21) is equal to the width of the magnetic gap (15), the length of the conducting magnet (22) is twice the length of the coil (25), and the center of the coil (25) corresponds to the center of the conducting magnet (22). In this way, magnetic resistance can be avoided in the whole process, and a movement assisted by the magnetic force can be generated, such that the inertial force in the direction of the movement can be increased, the rotating speed can be effectively improved, and thus the amount of the power being generated is improved. Meanwhile, the kinetic energy loss can be reduced, thereby improving the efficiency of energy conversion, and achieving the purpose of energy saving.

Description

Full load generator Technical field

The invention relates to the technical field of electromagnetic power generation, in particular to a full-load power generation device capable of avoiding magnetic resistance, increasing magnetic assistance and reducing motion loss, so as to improve the operation rate and cutting frequency of the electromagnetic power generation device. In order to increase its energy conversion rate, energy conservation and effective increase of its power generation.

Background technique

In general, the electromagnetic power generation device is composed of an induction group and a magnetic group, wherein the induction group is provided with at least one coil on at least one of the magnets, and the magnetic group is provided with two magnetic members at both ends of the axis of the induction group. The two magnetic members are arranged with opposite pole magnetic poles, and the magnetic group and the sensing group can be respectively defined as a rotor and a stator, and the relative linear or rotational motion causes the coil of the sensing group to be induced by the magnetic line cutting of the magnetic group. The electromotive force, in turn, achieves the purpose of power generation.

When the electromagnetic power generating device is actuated, when the coil of the induction group is connected to the load, the coil is magnetized, and under the induction of the polarity of the magnetic pole of the magnetic group, magnetic changes are generated at both ends of the coil to make it magnetic. The magnetic components of the group generate magnetoresistance, so the conventional electromagnetic power generation device will have kinetic energy loss caused by the magnetoresistance effect of anti-energy proliferation under load, and the energy conversion rate thereof will decrease;

In other words, since the existing electromagnetic power generation device is affected by the magnetoresistance effect of the anti-energy proliferation, the operation kinetic energy is lost and the speed of the movement is reduced. Therefore, how to solve the aforementioned problems is an urgent need of the industry.

In view of this, the present inventors have intensively discussed the problems faced by the aforementioned existing electromagnetic power generation devices, and have actively pursued solutions through years of research and development experience in related industries, and have been continuously researching and trialing. Finally, a full-load power generation device was successfully developed to overcome the kinetic energy loss caused by the magnetoresistance effect of the anti-energy proliferation of the existing electromagnetic power generation device.

Summary of the invention

Therefore, the main object of the present invention is to provide a full-load power generation device which can reduce energy loss by virtue of avoiding magnetic resistance, thereby improving energy conversion efficiency and achieving energy saving.

Further, the second main object of the present invention is to provide a full-load power generating device capable of effectively increasing the rotational speed and increasing the amount of power generation by the magnetic boosting force thereof.

Further, another main object of the present invention is to provide a full-load power generating device capable of forming micro-power generation under the avoidance of magnetic resistance and magnetic acceleration, and improving the practicability of the power generating device.

Furthermore, another main object of the present invention is to provide a full-load power generating device which can effectively simplify the structure, in addition to reducing the cost, and improving the reliability of the overall operation.

Based on this, the present invention mainly achieves the foregoing objects and effects by the following technical means:

A full-load power generation device, which is composed of a magnetic column group and an induction column group, and the magnetic column group and the sensing column group can generate relative motion;

The magnetic column group is arranged with at least one first magnetic member and at least one second magnetic member in a moving direction, and each of the first magnetic member and the second magnetic member has the same length, and each of the first magnetic member and the second magnetic member The magnets are magnetized in the moving direction, and the magnetic poles of the adjacent first magnetic member and the second magnetic member are adjacent to each other, and the adjacent first magnetic member, second magnetic member or second magnetic member, and first magnetic member Having a magnetic gap of one equal width, the length of each of the first magnetic member and the second magnetic member is equal to the width of the magnetic gap;

The sensing column group is disposed in parallel on one side of the magnetic column group, and the sensing column group respectively has one or more coaxial line sensing members, and each of the sensing members has a magnetizer and a coil wound around the magnetizer. And each of the coils is connected with a load, so that the sensing column group can be excited in the moving direction when the load is connected, and the coil length of each of the sensing members is equal to the width of the magnetic gap, and the length of the magnetizer is twice the length of the coil, and the coil The center is opposite to the center of the magnetizer.

Wherein: the two ends of the magnet of the sensing component of the sensing column are respectively formed with a yoke of the same diameter as the coil, and the yokes of the two ends of the magnetizing magnet are respectively disposed on the opposite sides of the coil.

A full-load power generation device is characterized in that it is composed of two or more magnetic column groups and two or more groups of sensing columns, and each of the magnetic column groups is disposed at opposite intervals of the same pole, and each of the sensing groups The column groups are respectively equidistantly disposed between the two pairs of opposite magnetic column groups, and each of the magnetic column groups and each of the sensing column groups can synchronously generate relative motion;

Each of the magnetic arrays has at least one first magnetic member and at least one second magnetic member arranged in a moving direction, and each of the first magnetic member and the second magnetic member has the same length, and each of the first magnetic members and the second The magnetic member is magnetized in the moving direction, and the magnetic poles of the adjacent first magnetic member and the second magnetic member are adjacent to the same pole, and the adjacent first magnetic member, second magnetic member or second magnetic member, first magnetic member Between the first magnetic member and the second magnetic member, the length of each of the first magnetic member and the second magnetic member is equal to the width of the magnetic gap;

Each of the sensing arrays is disposed in parallel with one side of the magnetic array, and the sensing arrays respectively have one or more coaxial sensing members, and each of the sensing members has a magnet and a coil wound around the magnet. And each of the coils is connected with a load, so that the sensing column group can be excited in the moving direction when the load is connected, and then The length of the coil of each of the sensing members is equal to the width of the magnetic gap, and the length of the magnetic conductor is twice the length of the coil, and the center of the coil is opposite to the center of the magnetizer.

Wherein: the full-load power generation device is a disk type matrix generator, which is formed by interleaving at least one magnetic disk and at least one coil disk, and each of the magnetic disks is provided with at least one magnetic column group, and each of the coil disks is provided At least one sensing column group is disposed, and the magnetic column group and the sensing column group are opposite to each other.

Wherein: the sensing elements of each of the opposite sensing column groups are aligned with respect to the position of the magnetic column group relative to the magnetic member to improve the magnetic assistance at the same time point.

Wherein: the sensing parts of each of the opposite sensing column groups are arranged in a wrong position corresponding to the position of the magnetic column group relative to the magnetic member, so that the magnetic column group can be continuously pushed to improve the inertial force in the moving direction.

Wherein, the two ends of the magnet of the sensing element of each of the sensing columns are respectively formed with a yoke of the same diameter as the coil, and the yokes of the two ends of each of the guiding magnets are opposite to the inner side of the coil.

A full-load power generating device is characterized in that: two or more magnetic column groups and two or more sensing column groups are formed, and each of the magnetic column groups is arranged side by side in parallel with each other, and each of the sensing electrodes The column groups are respectively equidistantly disposed on one side of the two-two-phase magnetic column group, and each of the magnetic column groups and each of the sensing column groups can synchronously generate relative motion;

Each of the magnetic arrays has at least one first magnetic member and at least one second magnetic member arranged in a moving direction, and each of the first magnetic member and the second magnetic member has the same length, and each of the first magnetic members and the second The magnetic member is magnetized in the moving direction, and the magnetic poles of the adjacent first magnetic member and the second magnetic member are adjacent to the same pole, and the adjacent first magnetic member, second magnetic member or second magnetic member, first magnetic member Between the first magnetic member and the second magnetic member, the length of each of the first magnetic member and the second magnetic member is equal to the width of the magnetic gap;

Each of the sensing arrays is disposed in parallel with one side of the magnetic array, and the sensing arrays respectively have one or more coaxial sensing members, and each of the sensing members has a magnet and a coil wound around the magnet. And each of the coils is connected with a load, so that the sensing array can be excited in the moving direction when the load is connected, and the length of each of the sensing members is equal to the width of the magnetic gap, and the length of the magnetic conductor is twice the length of the coil, and The center of the coil is opposite the center of the magnetizer.

Wherein: the full-load power generation device may be a ring-type matrix generator, which is formed by interlacing at least one magnetic disk and at least one coil disk, and each of the magnetic disks is provided with at least two concentric magnetic column groups, and Each of the coil disks is provided with at least two coaxial inductive array groups, and each of the same-diameter magnetic column groups and the sensing column group are opposite each other, and the first magnetic members of the phase-aligned magnetic column groups of the magnetic disks The two ends of the second magnetic member are correspondingly bundled toward the axis, and the magnetizers of the sensing members of the phase-inductive array of the coil plates and the two ends of the coil are also correspondingly bundled toward the axis.

Wherein: the sensing elements of each of the inductive column groups correspond to the magnetic column group and the positions of the magnetic members are aligned to improve the magnetic assistance at the same time point.

Wherein: the sensing elements of each of the inductive column groups correspond to the magnetic column group and the magnetic members are arranged in a misaligned position, so that the magnetic column group can be continuously pushed to improve the inertial force in the moving direction.

Wherein, the two ends of the magnet of the sensing element of each of the sensing columns are respectively formed with a yoke of the same diameter as the coil, and the yokes of the two ends of each of the guiding magnets are opposite to the inner side of the coil.

In this way, the full-load power generating device of the present invention is designed to completely avoid the magnetic resistance during the movement through the special ratio design of the magnetizer of the sensing member and the coil, the magnetic member and the magnetic gap, and to promote the magnetic assistance in the forward direction, except for the micro force. In addition to the function of power generation, it can effectively improve its energy conversion rate, further achieve energy-saving effects, and can increase the power generation capacity under the acceleration of magnetic assistance, so it can greatly enhance its added value and improve its economic benefits.

In order to provide a further understanding of the present invention, the present invention, the preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, .

DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a block diagram showing a preferred embodiment of a full load power generating apparatus of the present invention.

2A to 2E are schematic views showing the operation of a preferred embodiment of the full-load power generating device of the present invention, for explaining that the magnetic members of the magnetic array are in an N-N adjacent operation state.

3A-3E are another schematic views of the operation of the preferred embodiment of the full-load power generating device of the present invention, for explaining that the magnetic members of the magnetic array are in an adjacent operation state of the S-S.

4 is a schematic structural view of another preferred embodiment of the full-load power generating device of the present invention for explaining the state of the disk matrix.

Fig. 5 is a perspective view showing the embodiment of the full load power generating device of Fig. 4 of the present invention.

Fig. 6 is a block diagram showing the structure of the next preferred embodiment of the full-load power generating device of the present invention for explaining the state of the ring matrix.

Fig. 7 is a perspective view showing the embodiment of the full load power generating device of Fig. 6 of the present invention.

Fig. 8 is a plan view showing the sensing member of the sensing array in the full-load power generating device of the present invention, for further explaining the state of the magnetizer.

Fig. 9 is a perspective view showing still another preferred embodiment of the full load power generating device of the present invention.

DESCRIPTION OF REFERENCE NUMERALS: 10 magnetic column group; 11 first magnetic member; 12 second magnetic member; 15 magnetic gap; 20 induction Column group; 21 sensing member; 22 magnetizer; 220 yoke; 25 coil; 1 disk; 100 shaft hole; 105 key portion; 2 coil disk; 200 shaft hole; 3 rotating shaft; 300 key portion.

detailed description

The present invention is a full load power generating device, with reference to the drawings and specific embodiments of the present invention and its components, 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 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 configuration of the full-load power generator of the present invention is composed of one or more magnetic arrays 10 and one or more sensing arrays 20 as shown in FIGS. 1 and 4, and each of them The magnetic arrays 10 are disposed at opposite intervals of the same pole, and each of the sensing arrays 20 are equally spaced between two pairs of opposite magnetic arrays 10 (as shown in FIG. 4) or one of the magnetic arrays 10 Side (as shown in FIG. 1), each of the magnetic arrays 10 and each of the sensing arrays 20 can be defined as a rotor or a stator, respectively, and can synchronously generate relative motion;

Each of the magnetic arrays 10 has at least one first magnetic member 11 and at least one second magnetic member 12 arranged in the moving direction, and each of the first magnetic member and the second magnetic member 11 and 12 has the same length, and each of the plurality of magnetic members 11 and 12 The first magnetic member and the second magnetic member 11 and 12 are magnetized in the moving direction, and the magnetic poles of the adjacent first magnetic member and the second magnetic member 11 and 12 are adjacent to each other, for example, the N pole corresponds to the N pole (eg, 1 or 2) or the S pole corresponds to the S pole (as shown in FIG. 3), and the adjacent first magnetic member, second magnetic member 11, 12, or second magnetic member, first magnetic member 12 11 has a magnetic gap 15 of equal width, and the length of each of the first magnetic member and the second magnetic member 11, 12 is equal to the width of the magnetic gap 15;

Each of the sensing arrays 20 has one or more coaxial sensing members 21, and each of the sensing members 21 has a magnet 22 and a coil 25 wound around the magnet 22, and each of the coils 25 is connected The load (not shown) causes the sensing array 20 to be excited in the moving direction when the load is connected, and the length of the coil 25 of each of the sensing members 21 is equal to the width of the magnetic gap 15, and the magnetic conductor 22 of each of the sensing members 21 The length is twice the length of the coil 25, and the center of the coil 25 is opposite to the center of the magnetizer 22;

In this way, the group constitutes a full-load power generating device that can avoid magnetic resistance and proliferate magnetic assistance.

As for the preferred embodiment of the present invention, when the actual operation is performed, for example, when each of the magnetic arrays 10 and the sensing arrays 20 are in relative motion, for example, in the embodiment, the magnetic array 10 is used as the rotor to be displaced from right to left. The sensing column group 20 is used as the stator when it is not moving. As shown in FIG. 2, when the displacement is displayed, the magnetic array 10 is moved from the N-pole of the first magnetic member 11 to the N-pole of the second magnetic member 12. First First, as shown in FIG. 2A, in the sensing column group 20, the sensing line 21 of the first magnetic member 11 of the corresponding magnetic column group 10 of the sensing member 21 is started. At this time, since the coil 25 is connected to the load, when the coil 25 enters the magnetic gap 15, the sensing member 21 The first magnetic member 11 corresponding to the magnetic column group 10 is inductively affected, so that the two ends of the sensing member 21 corresponding to the first magnetic member 11 are different magnetic poles, and the sensing member 21 is formed into the corresponding magnetic column group 10. The entry end is the S pole, the exit end of the corresponding magnetic column group 10 is the N pole, and since the magnetizer 22 of the sensing member 21 is twice as long as the coil 25, the two ends of the magnetizer 22 are located in the second magnetic member, A magnetic member 12, 11 and a magnetic gap 15 of the first magnetic member and the second magnetic member 11, 12 are in a neutral line, so that the N end of the magnet 22 of the sensing member 21 sucks the S end of the corresponding first magnetic member 11, and The end of the magnetizer 22S will suck the N end of the corresponding second magnetic member 12, completely avoiding the magnetic resistance, and further forming a magnetic assisting force for the moving direction;

Next, as shown in FIG. 2B, at this time, the coil 25 of the sensing member 21 is in the process of the magnetic gap 15 between the first magnetic member and the second magnetic member 11, 12, in addition to generating power generation by magnetic line cutting, when the sensing column The polarity of the sensing member 21 when the end of the coil 25 of the inductive component 21 of the group 20 corresponding to the entry end of the magnetic array 10 corresponds to the neutral of the magnetic gap 15 of the first magnetic member and the second magnetic member 11 and 12 of the magnetic array 10 The conversion occurs, and the inductive member 21 corresponds to the N-pole of the entry end of the magnetic array 10, and the exit end of the corresponding magnetic array 10 is the S-pole, which is designed according to the extension length of the magnetizer 22 of the sensing member 21. The magnet 22 corresponds to the N pole pole end portion of the corresponding second magnetic member 12 corresponding to the entrance end of the magnetic array 10, and the S pole magnetic of the corresponding first magnetic member 11 is pushed correspondingly to the exit end of the corresponding magnetic array 10 The extreme portion, and because the magnetic array 10 is moving, it causes the conductive magnet 22 to pass over the N pole pole end of the second magnetic member 12 corresponding to the entry end of the magnetic array 10, and the exit end of the corresponding magnetic array 10 is crossed. The S pole pole end portion of the first magnetic member 11 generates a forward thrust which is repulsive with the same pole, and completely avoids the magnetic resistance and forms Shares in favor of the direction of movement of magnetic power;

Then, as shown in FIG. 2C, at this time, the coil 25 of the sensing member 21 is still moved in the magnetic gap 15 between the first magnetic member and the second magnetic member 11, 12, so that the power generation function of the magnetic line cutting can be continued, and when the sensing column is When the center line of the group 20 inductive member 21 corresponds to the center line of the magnetic gap 15 between the first magnetic member and the second magnetic member 11 and 12 of the magnetic array unit 10, the polarity of the sensing member 21 is constant at both ends, and at this time, due to the sensing member 21 The two ends of the magnetizer 22 respectively correspond to the lines of the first magnetic member and the second magnetic member 11 and 12, so that when the magnetic column group 10 is moved, the magnetizer 22 will pass the second end of the magnetic column group 10 to the second end. The magnetic member 12 is lined up and sucks the S pole pole end portion of the second magnetic member 12, and the magnetizer 22 passes over the line of the first magnetic member 11 corresponding to the exit end of the magnetic column group 10, and sucks the first magnetic member 11 The N-pole magnetic pole tip for generating a forward suction of a heteropolar attraction, and completely avoiding the reluctance, thereby forming a favorable motion Directional magnetic assistance;

Then, as shown in FIG. 2D, at this time, the portion of the coil 25 of the sensing member 21 that moves in the magnetic gap 15 between the first magnetic member and the second magnetic member 11 and 12 can still generate power due to magnetic line cutting. When the end of the coil 25 of the inductive array 20 in the sensing member 21 corresponding to the exit end of the magnetic array 10 corresponds to the center line of the magnetic gap 15 between the first magnetic member and the second magnetic member 11 and 12 of the magnetic array 10, the sensing member 21 The polarity of the sensing element 21 is changed to the S pole of the corresponding magnetic column group 10, and the leaving end of the corresponding magnetic column group 10 is the N pole. Due to the extension length of the magnetizer 22 of the sensing member 21, Corresponding to the entrance end of the magnetic array 10 of the magnetizer 22, the corresponding S pole pole end portion of the second magnetic member 12 is pushed, and the exit end of the corresponding magnetic column group 10 is pushed to the corresponding N of the first magnetic member 11 The pole pole tip portion, and because the magnetic array 10 is in operation, it causes the magnetizer 22 to pass the entry end of the magnetic array 10 past the S pole pole end portion of the second magnetic member 12, and the corresponding magnetic column group 10 The exit end of the first magnetic member 11 passes over the N-pole pole end portion of the first magnetic member 11 to generate a forward thrust repulsive forward thrust, so that it can be completely returned Reluctance to form a magnetic favor an assist direction of motion;

Finally, as shown in FIG. 2E, when the magnetic column group 10 continues to be displaced, the line of the sensing member 21 of the sensing column group 20 corresponds to the line of the second magnetic member 12 of the magnetic column group 10, so that the entire sensing member 21 coil 25 corresponds to the first The two magnetic members 12 are formed in a completely non-power generating state without an inductive polarity, but the coil 25 then crosses the S pole pole end portion of the second magnetic member 12 of the magnetic array 10 and enters the second magnetic field of the magnetic array 10 The magnetic gap 15 between the first magnetic members 12 and 11 forms a new operating state as shown in FIG.

As shown in FIG. 3, when the displacement is displayed, the magnetic array 10 is moved from the S pole of the second magnetic member 12 toward the S pole of the first magnetic member 11. First, as shown in FIG. 3A, the line of the second magnetic member 12 of the line-corresponding group 10 of the sensing group 20 is started. At this time, since the coil 25 is connected to the load, when the coil 25 enters the magnetic gap 15, the sensing unit 21 is sensitive to the polarity of the second magnetic member 12 corresponding to the magnetic array 10, so that the two ends of the sensing member 21 are different from the two ends of the second magnetic member 12, and the corresponding magnetic members of the sensing member 21 are present. The entry end of the group 10 is N pole, the exit end of the corresponding magnetic column group 10 is S pole, and since the magnetizer 22 of the sensing member 21 is twice as long as the coil 25, the two ends of the magnetizer 22 are located at the first magnetic pole. The middle of the magnetic gap 15 between the second magnetic member 11, 12 and the second magnetic member and the first magnetic member 12, 11 causes the S end of the magnet 22 of the sensing member 21 to suck the corresponding second magnetic member 12. The N end, and the N end of the magnetizer 22 will suck the S end of the corresponding first magnetic member 11, and completely avoid the magnetic resistance, forming a magnetic assisting force for the direction of motion;

Next, as shown in FIG. 3B, at this time, the coil 25 of the sensing member 21 is in the process of the magnetic gap 15 between the second magnetic member and the first magnetic members 12, 11, in addition to generating power generation by magnetic line cutting, When the end of the coil 25 of the inductive component 21 of the corresponding group of the magnetic field group 10 corresponds to the second magnetic member of the magnetic array 10 and the neutral line of the magnetic gap 15 between the first magnetic members 12 and 11, the sensing member The polarity of 21 is converted, and the inductive member 21 is the S pole of the corresponding magnetic column group 10 and the N pole of the corresponding magnetic column group 10, and the extension length of the magnetizer 22 of the sensing member 21 is designed. So that the entrance end of the magnetic field group 10 corresponding to the magnetizer 22 will push the corresponding S pole pole end portion of the first magnetic member 11, and the exit end of the corresponding magnetic column group 10 will push the corresponding second magnetic member 12 The N-pole magnetic pole end portion, and because the magnetic column group 10 continues to move, it causes the magnetizing magnet 22 to pass the S pole pole end portion of the first magnetic member 11 corresponding to the entrance end of the magnetic column group 10, and the corresponding magnetic column group 10 The exit end passes over the N pole pole end portion of the corresponding second magnetic member 12, generating a forward thrust that is repulsive with the same pole, and completely avoids the magnetic resistance to form a magnetic assist force that is favorable for the moving direction;

Then, as shown in FIG. 3C, at this time, the coil 25 of the sensing member 21 is still moved in the magnetic gap 15 between the second magnetic member and the first magnetic members 12, 11, so that the power generation function of the magnetic line cutting can be continuously generated, and when the sensing column is When the middle of the group 20 sensing member 21 corresponds to the line between the second magnetic member and the first magnetic member 12 and 11 of the magnetic gap 15, the polarity of the sensing member 21 is constant. The two ends of the magnetizer 22 correspond to the second magnetic member and the first magnetic member 12, 11 respectively, so that under the operational movement of the magnetic array 10, the magnetic conductor 22 is caused to pass over the entry end of the magnetic array 10 The first magnetic member 11 is lined up and sucks the N pole pole end portion of the first magnetic member 11, and the magnetizer 22 passes the line of the second magnetic member 12 corresponding to the exit end of the magnetic array 10, and sucks the second magnetic The S pole pole end of the piece 12 is used to generate a forward suction of a heteropolar attraction, and completely avoids the magnetic resistance, thereby forming a magnetic assisting force for the direction of motion;

Then, as shown in FIG. 3D, at this time, the portion of the coil 25 of the sensing member 21 that moves in the magnetic gap 15 between the second magnetic member and the first magnetic members 12, 11 can still generate power by cutting the magnetic lines. When the end of the coil 25 of the sensing member group 21 corresponding to the exit end of the magnetic column group 10 corresponds to the second magnetic member of the magnetic array group 10 and the neutral line of the magnetic gap 15 between the first magnetic members 12 and 11, the sensing member The induced polarity of 21 is again converted, and the inductive member 21 is N-pole corresponding to the entry end of the magnetic column group 10, and the exit end of the corresponding magnetic column group 10 is S-pole, due to the extension length of the magnetizer 22 of the sensing member 21. The design is such that the entrance end of the magnetic field group 10 corresponding to the magnetizer 22 will push the corresponding N pole pole end portion of the first magnetic member 11 and the exit end of the corresponding magnetic column group 10 will push the corresponding second magnetic member 12 The S pole pole end portion, and because the magnetic array 10 continues to move, it causes the magnetizer 22 to pass the entry end of the magnetic array 10 over the N pole pole end portion of the first magnetic member 11 and the corresponding magnetic column The exit end of the group 10 passes over the S pole pole end of the second magnetic member 12, generating a forward thrust that is repulsive with the same pole. Full evade reluctance, shape Become a magnetic boost that is beneficial to the direction of motion;

Finally, as shown in FIG. 3E, when the magnetic array 10 continues to be displaced, the line of the sensing member 21 of the sensing array 20 corresponds to the line of the first magnetic member 11 of the magnetic array 10, so that the entire sensing member 21 coil 25 corresponds to the first The magnetic member 11 is formed in a completely non-power generating state without an inductive polarity, but when the coil 25 of the sensing member 21 crosses the N-pole pole end portion of the first magnetic member 11 of the magnetic array 10, the magnetic column group 10 is entered. The magnetic gap 15 between the first magnetic member and the second magnetic member 11 and 12 is circulated to form a state as shown in FIG. 2A, and the two ends of the sensing member 21 are again brought into phase with the opposite ends of the corresponding first magnetic member 11. The opposite polarity is such that the inductive member 21 corresponds to the entry end of the magnetic column group 10 as the S pole, and the exit end of the corresponding magnetic column group 10 is the N pole for forming such a cyclic operation.

As can be seen from the above structural design and operation description, the full-load power generating device of the present invention utilizes the magnetizer 22 of the inductive array 20 to be twice the length of the coil 25 and the first magnetic member, the second magnetic members 11, 12, and the magnetic gap 15. The design can make the coil 25 of the sensing component 21 of the sensing array 20 can be connected to the load in the most simple structure to form a full-load state, so that the magnetic resistance and the magnetic acceleration can be completely avoided in the whole process, and the sensing array 20 is added. The rate of relative movement with the magnetic array 10 can reduce the kinetic energy loss, thereby improving the energy conversion efficiency and achieving the goal of energy saving, and can effectively increase the rotational speed and increase the power generation.

Further, under the avoidance of the magnetic resistance and the magnetic acceleration, the utility model can be applied to the micro-power generation, and the utility of the power generation device can be improved, and the structure can be simplified, thereby reducing the cost and improving the reliability of the overall operation.

Another preferred embodiment of the present invention is shown in FIG. 4 and FIG. 5. The embodiment is a disk type matrix generator which is formed by interleaving at least one magnetic disk 1 and at least one coil disk 2. Each of the magnetic disks 1 is provided with at least one magnetic column group 10 which are opposite to each other in the same polarity, so that the magnetic current is oriented and the magnetic wires are dense, and each of the coil disks 2 is provided with at least one sensing column group 20, and the magnetic column The group 10 is opposite to the sensing array 20, and each of the magnetic disk 1 and each of the coil disks 2 can be respectively defined as a rotor or a stator for synchronously moving relative to each other. And each of the coils 2 as a stator is a preferred embodiment, and a shaft hole 100 and 200 are respectively formed in the center of each of the magnetic disk 1 and each of the coil disks 2 for pivoting a rotating shaft 3 and a shaft hole of the disk 1 100 and the rotating shaft 3 are formed with corresponding key portions 105, 300, so that the magnetic disk 1 can be rotated by the rotating shaft 3 relative to the coil disk 2, and the sensing member 21 of each of the opposing sensing arrays 20 corresponds to the magnetic column group 10 The positions of a magnetic member and the second magnetic members 11 and 12 may be arranged in an alignment or a misalignment to increase the same time point. Or a magnetic power of the magnetic column group 10 can promote sustained action, can effectively increase the inertia force of the direction of movement.

6 and 7, which is a second preferred embodiment of the present invention, the embodiment is in the form of a ring. a matrix generator, which is formed by interlacing at least one magnetic disk 1 and at least one coil disk 2, and each of the magnetic disks 1 is provided with at least two concentric magnetic field groups 10 which are mutually homopolar and The magnetic current is oriented and the magnetic wire is dense, and each of the coil disks 2 is provided with at least two coaxial sensing arrays 20, and each of the magnetic columns 10 of the same diameter and the sensing array 20 are opposite each other. Both ends of the first magnetic members 11A, 11B or the second magnetic members 12A, 12B of the phase magnetic groups 10A, 10B of the magnetic disk 1 are correspondingly bundled toward the axis, and the respective coil disks 2 are merged. The two ends of the sensing elements 21A, 21B of the sensing arrays 20A, 20B are also correspondingly converged toward the axis, and each of the magnetic disks 1 and each of the coil disks 2 can be defined as a rotor or a stator, respectively, for simultaneous generation. For the relative movement, the present invention is characterized in that each of the magnetic disk 1 is used as a rotor, and each of the coil disks 2 is used as a stator, and a shaft hole 100, 200 is formed in each of the magnetic disk 1 and each of the coil disks 2 respectively. a pivot shaft 3 is pivoted, and the disk 1 shaft hole 100 and the rotating shaft 3 are formed with corresponding key portions 105, 300, so that the magnetic disk 1 can be rotated by the shaft 3 The position of the first magnetic member and the second magnetic member 11 and 12 of the magnetic array 10 can be aligned or misaligned, and the position of the first magnetic member and the second magnetic member 11 and 12 of the magnetic array 10 can be aligned. Increasing the magnetic assistance at the same time point or enabling the magnetic array 10 to be pushed by the continuous action can effectively increase the inertial force in the direction of motion.

Further, as shown in FIG. 8, the two ends of the magnetizer 22 of the sensing member 21 of the sensing array 20 of the present invention are respectively formed with a yoke 220 having the same diameter as the coil 25. The yokes 220 of the two ends of the magnetizer 22 are opposite. The inner side can be attached to the two ends of the coil 25, so that the magnetic flux remaining on the coil 25 can be prevented from generating magnetic stress interference and the magnetic conductive effect of the magnetizer 22 can be enhanced, so that the magnetic conduction of the sensing member 21 to the two ends is different from each other. complete.

Thus, it can be understood that the present invention is an innovative utility model, which not only effectively solves the problems faced by the practitioners, but also greatly enhances the efficiency, and does not see the same or similar product utility models or disclosures in the same technical field. The use and the improvement of the efficacy at the same time, the invention has been in accordance with the novelty and inventive conditions of the invention patent, and the invention patent is filed according to law.

Claims (12)

A full-load power generation device, which is composed of a magnetic column group and an induction column group, and the magnetic column group and the sensing column group can generate relative motion; The magnetic column group is arranged with at least one first magnetic member and at least one second magnetic member in a moving direction, and each of the first magnetic member and the second magnetic member has the same length, and each of the first magnetic member and the second magnetic member The magnets are magnetized in the moving direction, and the magnetic poles of the adjacent first magnetic member and the second magnetic member are adjacent to each other, and the adjacent first magnetic member, second magnetic member or second magnetic member, and first magnetic member Having a magnetic gap of one equal width, the length of each of the first magnetic member and the second magnetic member is equal to the width of the magnetic gap; The sensing column group is disposed in parallel on one side of the magnetic column group, and the sensing column group respectively has one or more coaxial line sensing members, and each of the sensing members has a magnetizer and a coil wound around the magnetizer. And each of the coils is connected with a load, so that the sensing column group can be excited in the moving direction when the load is connected, and the coil length of each of the sensing members is equal to the width of the magnetic gap, and the length of the magnetizer is twice the length of the coil, and the coil The center is opposite to the center of the magnetizer. The full-load power generating device according to claim 1, wherein a magnetic yoke of the same diameter as the coil is formed at each end of the magnet of the sensing member of the sensing array, and the yokes of the two ends of the magnet are opposite to the inner side. The ends of the coil can be attached. A full-load power generation device is characterized in that it is composed of two or more magnetic column groups and two or more groups of sensing columns, and each of the magnetic column groups is disposed at opposite intervals of the same pole, and each of the sensing groups The column groups are respectively equidistantly disposed between the two pairs of opposite magnetic column groups, and each of the magnetic column groups and each of the sensing column groups can synchronously generate relative motion; Each of the magnetic arrays has at least one first magnetic member and at least one second magnetic member arranged in a moving direction, and each of the first magnetic member and the second magnetic member has the same length, and each of the first magnetic members and the second The magnetic member is magnetized in the moving direction, and the magnetic poles of the adjacent first magnetic member and the second magnetic member are adjacent to the same pole, and the adjacent first magnetic member, second magnetic member or second magnetic member, first magnetic member Between the first magnetic member and the second magnetic member, the length of each of the first magnetic member and the second magnetic member is equal to the width of the magnetic gap; Each of the sensing arrays is disposed in parallel with one side of the magnetic array, and the sensing arrays respectively have one or more coaxial sensing members, and each of the sensing members has a magnet and a coil wound around the magnet. And each of the coils is connected with a load, so that the sensing array can be excited in the moving direction when the load is connected, and the length of each of the sensing members is equal to the width of the magnetic gap, and the length of the magnetic conductor is twice the length of the coil, and The center of the coil is opposite the center of the magnetizer. The full load power generating device according to claim 3, wherein the full load power generating device is a disk type matrix generator, which is formed by interleaving at least one magnetic disk and at least one coil disk, each of the disks At least one magnetic column group is disposed, and each of the coil disks is provided with at least one sensing column group, and the magnetic column group and the sensing column group are opposite to each other. The full-load power generating device according to claim 3 or 4, wherein the sensing members of the opposite sensing arrays are aligned with respect to the position of the magnetic column group relative to the magnetic members to improve the magnetic assistance at the same time point. . The full-load power generating device according to claim 3 or 4, wherein the sensing members of the opposite sensing arrays are arranged in a dislocation relative to the position of the magnetic column group relative to the magnetic members, so that the magnetic array can be continuously driven. To increase the inertial force of the direction of motion. The full-load power generating device according to claim 3 or 4, wherein a magnetic yoke of the same diameter as the coil is formed at each end of the magnet of the sensing member of each of the sensing arrays, and magnetic fluxes at both ends of the magnet are respectively The yoke is opposite to the inner side for the ends of the coil to abut. A full-load power generating device is characterized in that: two or more magnetic column groups and two or more sensing column groups are formed, and each of the magnetic column groups is arranged side by side in parallel with each other, and each of the sensing electrodes The column groups are respectively equidistantly disposed on one side of the two-two-phase magnetic column group, and each of the magnetic column groups and each of the sensing column groups can synchronously generate relative motion; Each of the magnetic arrays has at least one first magnetic member and at least one second magnetic member arranged in a moving direction, and each of the first magnetic member and the second magnetic member has the same length, and each of the first magnetic members and the second The magnetic member is magnetized in the moving direction, and the magnetic poles of the adjacent first magnetic member and the second magnetic member are adjacent to the same pole, and the adjacent first magnetic member, second magnetic member or second magnetic member, first magnetic member Between the first magnetic member and the second magnetic member, the length of each of the first magnetic member and the second magnetic member is equal to the width of the magnetic gap; Each of the sensing arrays is disposed in parallel with one side of the magnetic array, and the sensing arrays respectively have one or more coaxial sensing members, and each of the sensing members has a magnet and a coil wound around the magnet. And each of the coils is connected with a load, so that the sensing array can be excited in the moving direction when the load is connected, and the length of each of the sensing members is equal to the width of the magnetic gap, and the length of the magnetic conductor is twice the length of the coil, and The center of the coil is opposite the center of the magnetizer. The full-load power generating device according to claim 8, wherein the full-load power generating device is a ring-type matrix generator, which is interleaved by at least one magnetic disk and at least one coil disk. Each of the magnetic disks is provided with a magnetic column group of at least two concentric cores, and each of the coil disks is provided with at least two coaxial sensing group groups, and each of the magnetic column groups and the sensing column groups of the same diameter are In a relative shape, the first magnetic member of the phase magnetic group of each of the magnetic disks and the two ends of the second magnetic member are correspondingly bundled toward the axis, and the sensing members of the phase-inducing array of the coil disks are respectively The two ends of the magnet and the coil are also correspondingly bundled toward the axis. The full-load power generating device according to claim 8 or 9, wherein the sensing members of the adjacent sensing arrays are aligned with the magnetic column group and the magnetic members are aligned to improve the same time point. Magnetic assistance. The full-load power generating device according to claim 8 or 9, wherein the sensing members of the adjacent sensing arrays are arranged in a position corresponding to the magnetic column group and the magnetic members are arranged in a misaligned manner, so that the magnetic array can be continued. The action is pushed to increase the inertial force in the direction of motion. The full-load power generating device according to claim 8 or 9, wherein a magnetic yoke of the same diameter as the coil is formed on each of the two ends of the magnet of the sensing member of each of the sensing arrays, and magnetic ends of the magnetic conductors are respectively The yoke is opposite to the inner side for the ends of the coil to abut.

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