WO2019213885A1

WO2019213885A1 - Magnetic disturbance generator and power generation method

Info

Publication number: WO2019213885A1
Application number: PCT/CN2018/086253
Authority: WO
Inventors: 刘远芳
Original assignee: Liu Yuanfang
Priority date: 2018-05-10
Filing date: 2018-05-10
Publication date: 2019-11-14
Also published as: CN109041588A

Abstract

A magnetic disturbance generator and a power generation method. The magnetic disturbance generator (10D) comprises a magnet assembly (11D), a magnetic core (12D), and at least one coil (13D); the magnet assembly (11D) comprises at least one permanent magnet (111D) to provide a magnetic field environment for the magnetic disturbance generator (10D) by means of the permanent magnet (111D); the magnetic core (12D) is made of a magnetic conductive material and comprises two ends (121D); at least one of the ends (121D) of the magnet core (12D) is close to the magnet assembly (11D) to form at least one magnetic gap (14D) between the magnet assembly (11D) and the end (121D) close thereto; the coil (13D) is sleeved on the magnetic core (12D), such that when the magnetic field within the magnetic gap (14D) changes in response to a change of the magnetic gap (14D), the magnetic core (12D) can respond to the change of the magnetic field within the magnetic gap (14D) to change the magnetic flux of the magnetic core (12D), thereby generating power through the coil (13D).

Description

Magnetic generator and power generation method

Technical field

The present invention relates to the field of generators, and more particularly to a snubber generator and a method of generating electricity to cause the oscillating generator to generate electrical energy by perturbing the magnetic field of the oscillating generator.

Background technique

The current power generation principle of the generator mainly utilizes the phenomenon of electromagnetic induction to generate an induced electromotive force in the coil by changing the magnetic flux of a coil in a magnetic field, and the magnitude of the induced electromotive force generated is the number of turns of the coil and the number of passes. The rate of change of the magnetic flux of the coil is proportional, wherein it is understood that the change in the magnetic flux of the coil is mainly dependent on the change of the magnetic field and the movement of the coil relative to the magnetic field, and therefore, in order to obtain a higher induced electromotive force, In terms of the parameter design of the generator itself, it should have a strong magnetic field environment and a large number of coil turns. Thus, in the current structural design of a generator that uses a permanent magnet to provide a magnetic field environment, the volume of the coil of the generator and the volume of the permanent magnet should have a larger proportion of generator volume.

However, the current generator multi-passes the relative movement between the coil and the permanent magnet to realize the change of the magnetic flux of the coil in the magnetic field provided by the permanent magnet, so as to convert the mechanical energy of the relative motion between the coil and the permanent magnet. For electrical energy, therefore, the current design of the generator is often reserved for the relative movement between the coil and the permanent magnet, and as previously described, the structure of the generator that provides the magnetic field environment using permanent magnets In the design, the volume of the coil of the generator and the volume of the permanent magnet have a larger proportion of the generator volume, so that the current generator has the space reserved for the relative movement between the coil and the permanent magnet. The larger generator volume ratio, that is to say, the current generator structure design has a large limitation on the ratio of the generator's power generation efficiency to its volume, so that the ratio of the current generator's power generation efficiency to its volume is difficult to be Further improvement, it is difficult to increase the power generation efficiency while reducing the volume of the current generator.

In addition, the current generator works in a single mode, and the mechanical energy is converted into electric energy mainly by the relative rotation or relative reciprocating motion between the coil and the permanent magnet, and the rotating motion type generator and the reciprocating motion are adopted. The structure of the generator of the motion type is very different, that is, the current generator has poor structural compatibility, and it cannot be converted into electric energy by being compatible with a plurality of motion modes at the same time, and therefore corresponds to the mechanical energy used by the generator. When the motion mode does not match the working mode of the generator, an additional mechanical structure is required to convert the motion mode corresponding to the mechanical energy into a motion mode consistent with the working mode of the generator, thus increasing the cost of the generator. The volume occupied by the work, on the other hand, also causes loss of the mechanical energy during the conversion of the motion mode, thereby reducing the power generation efficiency of the generator. In addition, the poor structural compatibility of current generators also limits the application of the generator. For example, when the generator is used as an action detection tool, it can only generate corresponding electrical signals in response to corresponding actuation actions. Cannot be compatible with the detection of multiple actuation actions. That is to say, in different application scenarios, the structural design of the generator is quite different, thus increasing the design and manufacturing cost of the current generator application in different application scenarios.

In summary, the current structural design of the generator is difficult to achieve both volume miniaturization and high power generation efficiency, and the current generator has poor structural compatibility, so that its working mode is single, and thus cannot be compatible with various motion modes. The conversion of mechanical energy into electrical energy, or the generation of corresponding electrical signals in response to a variety of actuations, thereby limiting the range of applications of current generators.

Summary of the invention

An object of the present invention is to provide a disturbance generator and a power generation method, wherein the disturbance generator includes at least one coil and utilizes a response state of a different medium to a magnetic field, that is, a magnetic property exhibited by a different medium, so that the The magnetic field of the disturbance generator can be varied in response to different media, such that the magnetic flux of the coil changes, thereby enabling the coil to generate electrical energy in response to changes in the magnetic flux of the coil.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the disturbance generator further includes a magnetic core, wherein the coil is sleeved on the magnetic core to pass the magnetic core to the magnetic field The response amplifies the amount of change in the magnetic flux of the coil, thereby increasing the power generation efficiency of the disturbance generator.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the disturbance generator further includes a magnet assembly to provide a magnetic field environment for the disturbance generator through the magnet assembly, thereby utilizing different The response of the medium to the magnetic field changes the magnetic flux of the coil to generate electrical energy to the coil.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the disturbance generator further has a magnetic gap, wherein the magnetic gap is formed between the magnetic core and the magnet assembly, Varying the magnetic field of the magnetic gap by a change in the medium in the magnetic gap, thereby increasing the amount of change in the magnetic flux of the coil by amplifying the magnetic field by the magnetic core in response to the magnetic field, thereby increasing the magnetic disturbance Generator power generation efficiency.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the disturbance generator further includes at least one magnetic medium to allow movement of the magnetic medium in the magnetic gap to cause the magnetic gap to be The medium changes to change the magnetic field of the magnetic gap, thereby changing the magnetic flux of the coil such that the coil is capable of generating electrical energy in response to changes in the magnetic flux of the coil.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the magnetic flux of the coil can be changed by the movement of the magnetic medium in the magnetic gap to enable the coil to respond to the magnetic flux of the coil The variably generating electrical energy is capable of maintaining the coil statically reducing the volume of the oscillating generator.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the magnetic flux of the coil in the magnetic field environment provided by the magnet assembly can be changed only by the movement of the magnetic medium in the magnetic gap, Thereby it is possible to maintain the coil and the magnet assembly to statically reduce the volume of the disturbance generator.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the magnetic flux of the coil in the magnetic field environment provided by the magnet assembly can be changed only by the movement of the magnetic medium in the magnetic gap, Thereby, it is advantageous to increase the volume ratio of the coil and the magnet assembly of the disturbance generator, thereby improving the power generation efficiency of the disturbance generator.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the magnetic flux of the coil can be changed by the movement of the magnetic medium in the magnetic gap to enable the coil to respond to the magnetic flux of the coil The varying electrical energy is generated to maintain the coil statically reducing the fatigue resistance requirements of the coil, thereby enhancing the stability of the disturbance generator.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the movement of the magnetic medium in the magnetic gap has various motion modes to enable the disturbance generator to respond to various motion modes. Ground converts mechanical energy into electrical energy.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the disturbance generator is capable of converting mechanical energy into electrical energy in response to a plurality of motion modes, thereby enhancing the applicability of the disturbance generator.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the disturbance generator can convert mechanical energy into electrical energy in response to various motion modes to avoid converting different motion modes into specific motions. The mechanical energy loss generated by the method further increases the power generation efficiency of the disturbance generator.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein the disturbance generator is capable of converting mechanical energy into electrical energy in response to various motions so that the disturbance generator can be used A corresponding electrical action is generated to detect a corresponding electrical action.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein a specific movement mode of the magnetic medium in the magnetic gap enables the direction of the magnetic induction line passing through the coil to be reversed, thereby increasing The amount of change in the magnetic flux of the coil further increases the power generation efficiency of the disturbance generator.

Another object of the present invention is to provide a magnetic disrupting generator and a power generating method, wherein the magnet assembly further includes a magnetic conductive component to change a magnetic field environment provided by the magnet assembly through the magnetic conductive component, thereby The magnetic field environment of the magnetic generator is matched with a specific movement mode of the magnetic medium in the magnetic gap, and the magnetic motion of the coil is caused by a specific movement mode of the magnetic medium in the magnetic gap. The direction of the line is reversed.

Another object of the present invention is to provide a disturbing magnet generator and a power generating method, wherein the magnetic core includes both end portions, wherein the magnetic gap is formed between the magnet assembly and the end of the magnetic core In order to enable the internal magnetic field of the magnetic core to directly change in response to a specific movement of the magnetic medium in the magnetic gap corresponding to the end portion, thereby when the magnetic core is set In the case of a U-shaped structure, the internal magnetic field of the magnetic core can also be reversely changed by the specific movement mode of the magnetic medium in the magnetic gap, so that the above-mentioned magnetic core can be added. The number of turns of the coil increases the power generation efficiency of the disturbance generator.

Another object of the present invention is to provide a disturbance generator and a power generation method, wherein a specific movement mode of the magnetic medium in the magnetic gap causes the magnetic medium to not move with the magnetic wave when moving in the magnetic gap The core and the magnet assembly collide, thereby reducing the operating noise of the disturbing generator.

In order to achieve at least one of the above objects, the present invention provides a disturbance generator, wherein the disturbance generator comprises:

At least one magnet assembly, wherein the magnet assembly includes at least one permanent magnet to provide a magnetic field environment for the disturbance generator by the permanent magnet;

At least one magnetic core, wherein the magnetic core is configured to be made of a magnetically permeable material and includes both ends, wherein at least one of the ends of the magnetic core is adjacent to the magnet assembly to the magnet assembly Forming at least one magnetic gap between the end of the magnetic core;

At least one coil, wherein the coil is looped over the magnetic core, such as when the magnetic field in the magnetic gap changes in response to a change in a medium within the magnetic gap, the magnetic core is responsive to the A change in the magnetic field within the magnetic gap causes the magnetic flux of the coil to be varied to generate electrical energy for the coil.

In one embodiment, the magnetic disrupting generator further includes at least one magnetic medium, wherein the magnetic medium is configured to be prepared using a magnetically permeable material to form a movement of the magnetic medium within the magnetic gap A change in the medium within the magnetic gap.

In an embodiment, the magnetic core is maintained static to the magnetic medium to increase the volume fraction of the coil to the disturbance generator, thereby increasing the power generation efficiency of the disturbance generator.

In an embodiment, the magnet assembly is maintained static for the magnetic medium to increase the volumetric proportion of the permanent magnet to the disturbance generator, thereby increasing the power generation efficiency of the disturbance generator.

In one embodiment, the magnet assembly has at least one first magnetic pole and at least one second magnetic pole, wherein at least one of the two ends of the magnetic core is respectively associated with the first magnetic pole and The second magnetic poles are adjacent to each other such that the magnetic gap is formed between the end portion and the first magnetic pole, and between the end portion and the second magnetic pole.

In an embodiment, the magnetic medium is configured to be capable of turning on the second magnetic pole and the ground at a position close to the magnetic gap to close the first magnetic pole and the end Switching between positions of the end portions to switch between the position of the magnetic medium near the end portion and the first magnetic pole and the position near the end portion and the second magnetic pole end The magnetic flux of the coil is varied to generate electrical energy for the coil.

In one embodiment, the magnet assembly has two first pole ends and two second pole ends, and the two ends of the core, that is, a first end and a second end The first end portion is respectively adjacent to one of the first magnetic poles and one of the second magnetic poles, the second end portion and the other of the first magnetic poles respectively And the other of the second pole ends is adjacent.

In an embodiment, the number of the magnetic media is two, that is, a first magnetic medium and a second magnetic medium, wherein the first magnetic medium and the second magnetic medium are set to be the first The second magnetic medium is in close proximity to the second end and the second end when the magnetic medium is adjacent to the first end and the first magnetic pole adjacent to the first end The second magnetic pole adjacent to the second magnetic medium, and when the first magnetic medium is adjacent to the first end and the second magnetic pole adjacent to the first end, the second magnetic medium Synchronizing the first end adjacent to the second end and the second end to form a pass through the coil by synchronous movement of the first magnetic medium and the second magnetic medium The reverse of the magnetic line of inductance, in turn, generates electrical energy to the coil.

In an embodiment, the magnetic core is disposed to have a U-shaped structure, wherein the two end portions of the magnetic core respectively correspond to both ends of the U-shape to be adapted to extend the magnetic core through the U-shaped structure The length, which in turn, increases the number of turns of the coil disposed on the magnetic core to increase the power generation efficiency of the disturbance generator.

In one embodiment, the two ends of the magnetic core, that is, a first end and a second end, wherein the first end corresponds to the first magnetic pole, the second An end portion corresponding to the second magnetic pole, such that the magnetic field is formed between the first end portion and the first magnetic pole end, and between the second end portion and the second magnetic pole end Gap.

In an embodiment, the magnetic medium is configured to be capable of approaching to increase the magnetic flux of the coil by turning on the first end and the first magnetic pole, and away from the first end and The first magnetic pole extremely reduces the magnetic flux of the coil, thereby changing the magnetic flux of the coil by the movement of the magnetic medium, thereby generating electrical energy for the coil.

In an embodiment, the magnetic medium is configured to be capable of approaching to increase the magnetic flux of the coil by turning on the second end and the second magnetic pole, and away from the second end and The second magnetic pole extremely reduces the magnetic flux of the coil, thereby changing the magnetic flux of the coil by the movement of the magnetic medium, thereby generating electrical energy for the coil.

In an embodiment, the magnetic medium is disposed to be capable of approaching to close the first end and the first magnetic pole to close the second end and the second Switching between positions of the magnetic poles by means of the magnetic medium at a position close to the first end and the first pole end and a position close to the second end and the second pole end The switching between the coils changes the magnetic flux of the coil, thereby generating electrical energy to the coil.

In an embodiment, the disturbance generator further includes a drive rod, wherein the drive rod has an active end and a passive end opposite the active end, wherein the drive rod is configured to be toggled The active end of the drive rod drives the passive end at a position near the first end and the first pole end and a position near the second end and the second pole end Switching, such as when the magnetic medium is disposed at the passive end, the magnetic medium is in the magnetic gap at a position near the first end and the first magnetic pole and close to the Switching between the position of the second end and the second pole end is controlled by the drive rod to toggle the drive rod to generate electrical energy at the coil.

In an embodiment, the magnetic medium is disposed to be rotatable about a position near the first end and the first magnetic pole and near the second end and the second magnetic pole Switching between positions to generate electrical energy by the rotation of the magnetic medium to the coil.

In one embodiment, the magnet assembly has two first magnetic poles and a second magnetic pole between the two first pole ends, and the two ends of the magnetic core, that is, a first end And a second end, wherein the first end corresponds to one of the second pole end and the two first pole ends, the second end corresponds to the second pole end and two The other of the first magnetic poles such that the magnetic gap is formed between the first end and the first magnetic pole and the second magnetic pole, respectively, and the second end is respectively The magnetic gap is formed between the first magnetic pole and the second magnetic pole.

In an embodiment, the magnetic medium is disposed to be close to a position to turn on the first end and the first magnetic pole, and close to turn on the first end and the first Switching between positions of the two magnetic poles by means of the magnetic medium at a position close to the first end and the first pole end and a position close to the first end and the second pole end Switching between them forms an inverse change in the magnetic line of inductance through the coil, thereby generating electrical energy in the coil.

In an embodiment, the magnetic medium is disposed to be close to a position to turn on the second end and the first magnetic pole, and close to turn on the second end and the first Switching between positions of the two magnetic poles by means of the magnetic medium at a position close to the second end and the first pole end and a position close to the second end and the second pole end Switching between them creates electrical energy generated by the coil in the reverse direction of the magnetic induction line of the coil.

In an embodiment, the disturbance generator comprises two magnetic media, namely a first magnetic medium and a second magnetic medium, wherein the first magnetic medium and the second magnetic medium are arranged to be When the first magnetic medium is adjacent to the first end and the first magnetic pole, the second magnetic medium is synchronously adjacent to the second end and the second magnetic pole, and when the first magnetic medium Proximate to the first end and the second magnetic pole, the second magnetic medium is in close proximity to the second end and the first magnetic pole to be by the first magnetic medium and the The synchronous movement of the second magnetic medium forms an inverse change in the magnetic line of inductance through the coil, thereby generating electrical energy in the coil.

In an embodiment, the disturbance generator further includes a link, wherein the first magnetic medium and the second magnetic medium are respectively disposed at two ends of the link to be connected by the connection The connection of the rod to the first magnetic medium and the second magnetic medium enables the first magnetic medium and the second magnetic medium to be driven in synchronism with each other.

In an embodiment, the disturbance generator further includes a reset element, wherein the reset element is configured to maintain an initial state of the first magnetic medium and the second magnetic medium, wherein in the initial a state in which the first magnetic medium is maintained near the first end and the first magnetic pole, and the second magnetic medium is maintained near the second end and the second a position of the magnetic pole such that when the first magnetic medium is driven by an external force to a position close to the first end and the second magnetic pole, and the second magnetic medium is driven synchronously to the first The reset element is capable of resetting the first magnetic medium and the second magnetic medium to the initial state after the external force is released when the two ends are at the position of the first magnetic pole.

In an embodiment, the disturbance generator further includes a drive rod, wherein the drive rod has an active end and a passive end opposite the active end, wherein the drive rod is configured to be toggled The drive end of the drive rod drives the passive end to swing between the first end and the second end, wherein the link is pivotally disposed on the drive rod The passive end drives a synchronous movement of the first magnetic medium and the second magnetic medium by a toggle of the driving end of the drive rod.

In an embodiment, the first magnetic medium and the second magnetic medium are arranged to synchronize the second magnetic medium when the first magnetic medium is close to the first end and the first magnetic pole Adjacent to the second end and the second magnetic pole, and when the first magnetic medium is adjacent to the second end and the first magnetic pole, the second magnetic medium is synchronized to the first An end portion and the second magnetic pole to form an inverse change in a magnetic line of inductance passing through the coil by synchronous movement of the first magnetic medium and the second magnetic medium, thereby generating the coil Electrical energy.

In an embodiment, the first magnetic medium and the second magnetic medium are arranged to move synchronously in a concentric manner such that the first magnetic medium can be rotatably adjacent to the first end and Switching between a position of the first magnetic pole and a position near the second end and the first magnetic pole, and the second magnetic medium is synchronously adjacent to the second end and the second magnetic The extreme position is switched between a position near the first end and the second pole end.

According to another aspect of the present invention, there is also provided a method of disturbing magnetic power generation comprising the steps of:

(a) bringing at least one end of a core of the loop having at least one coil adjacent to a magnet assembly to form at least one magnetic gap between the end and the magnet assembly;

(b) actuating at least one magnetic medium in the magnetic gap to change a medium in the magnetic gap by movement of the magnetic medium, thereby changing a magnetic field in the magnetic gap, and thereby the magnetic gap is The magnetic field in the coil changes the magnetic flux of the coil to generate electrical energy in response to the internal magnetic field.

Further objects and advantages of the present invention will be fully realized from the understanding of the appended claims.

DRAWINGS

1A and 1B are schematic diagrams showing the structure of a magnetic stirrer in different states according to an embodiment of the invention.

2A and 2B are schematic diagrams showing the structure of a magnetic stirrer in different states according to a modified embodiment of the above embodiment of the present invention.

3 is a perspective view showing the structure of a disturbing magnetic generator according to a further modified embodiment of the above-described embodiment of the present invention.

4A and 4B are schematic diagrams showing the structure of the above-described spoiler generator in different states according to the above embodiment of the present invention.

FIG. 5 is a perspective view showing the structure of the snubber generator according to a modified embodiment of the above embodiment of the present invention.

Fig. 6 is a schematic view showing the operation principle of the above-described spoiler generator according to the above embodiment of the present invention.

Fig. 7 is a structural schematic view showing a further modification of the disturbance generator according to the above embodiment of the present invention.

8A and 8B are schematic diagrams showing the structure of the spoiler generator in different states according to another embodiment of the present invention.

9A and 9B are schematic diagrams showing the structure of the spoiler generator in different states according to a modified embodiment of the above embodiment of the present invention.

10A and 10B are schematic diagrams showing the structure of a disturbing magnetic generator in different states according to another embodiment of the present invention.

Figure 11 is a block diagram showing the structure of the disturbance generator according to a variant embodiment of the above embodiment of the invention.

Figure 12 is a block diagram showing the structure of the disturbance generator according to a variant embodiment of the above embodiment of the present invention.

13A and 13B are schematic diagrams showing the structure of a disturbing magnetic generator in different states according to another embodiment of the present invention.

14A and 14B are schematic perspective structural views of a snubber generator according to a modified embodiment of the above embodiment of the present invention.

15A and 15B are schematic views showing the structure of the above-described spoiler generator in different states according to the above embodiment of the present invention.

Figure 16 is a flow chart showing the steps of a power generation method in accordance with an embodiment of the present invention.

detailed description

The following description is presented to disclose the invention to enable those skilled in the art to practice the invention. The preferred embodiments in the following description are by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention as defined in the following description may be applied to other embodiments, modifications, improvements, equivalents, and other embodiments without departing from the spirit and scope of the invention.

It should be understood by those skilled in the art that in the disclosure of the present invention, the terms "longitudinal", "transverse", "upper", "lower", "front", "back", "left", "right", " The orientation or positional relationship of the indications of "upright", "horizontal", "top", "bottom", "inside", "outside", etc. is based on the orientation or positional relationship shown in the drawings, which is merely for convenience of description of the present invention and The above description of the invention is not to be construed as a limitation of the invention.

It will be understood that the term "a" is understood to mean "at least one" or "one or more", that is, in one embodiment, the number of one element may be one, and in other embodiments, the element The number can be multiple, and the term "a" cannot be construed as limiting the quantity.

Referring to Figures 1A and 1B of the accompanying drawings of the present invention, a perturbation generator 10 in accordance with an embodiment of the present invention is illustrated, wherein Figures 1A and 1B respectively illustrate the perturbation generator 10 is a structural diagram of a different state, wherein the disturbance generator 10 includes a magnet assembly 11, a magnetic core 12, and a coil 13, wherein the magnet assembly 11 includes a permanent magnet 111 to pass the The magnet 111 provides a magnetic field environment for the disturbance generator 10, wherein the magnetic core 12 is configured to be made of a magnetically permeable material and includes both end portions 121, wherein one of the ends 121 of the magnetic core 12 is The magnet assembly 11 is adjacent to form at least one magnetic gap 14 between the magnet assembly 11 and the end portion 121 of the magnetic core 12, wherein the coil 13 is looped around the magnetic core 12. The magnetic flux of the coil 13 in response to a change in the magnetic field in the magnetic gap 14 when the magnetic field in the magnetic gap 14 changes in response to a change in the magnetic gap 14 It is changed so that the coil 13 generates electric energy.

In particular, in this embodiment of the invention, the disturbance generator 10 further includes a magnetic medium 15, wherein the magnetic medium 15 is configured to be made of a magnetically permeable material to be Movement within the magnetic gap 14 forms a change in the medium within the magnetic gap 14, i.e., a change in the magnetic gap 14, such that a magnetic field within the magnetic gap 14 is responsive to a medium within the magnetic gap 14. The change changes to cause the magnetic core 12 to generate electric energy to the coil 13 in response to a change in the magnetic field in the magnetic gap 14 to change the magnetic flux of the coil 13.

It can be understood that the change of the medium in the magnetic gap 14 and the change in the spatial size of the magnetic gap 14 itself can change the magnetic field in the magnetic gap 14 as a change of the magnetic gap 14. The invention is not limited thereto.

It is worth mentioning that, in this embodiment of the invention, the magnetic core 12 is maintained static to the magnetic medium 15 such that the coil 13 that is looped over the magnetic core 12 can be maintained stationary. The requirement for the fatigue resistance of the coil 13 is reduced, thereby enhancing the stability of the disturbance generator 10. In addition, the coil 13 is maintained static so that there is no need to reserve the movement space of the coil 13 in the structural design of the disturbance generator 10, which is advantageous for reducing the volume of the disturbance generator 10. In other words, in the case where the volume of the disturbance generator 10 is maintained, the coil 13 is maintained static so that the coil 13 does not need to be reserved in the structural design of the disturbance generator 10. The movement space is such that it is advantageous to increase the volume ratio of the coil 13 of the disturbance generator 10, thereby improving the power generation efficiency of the disturbance generator 10.

Furthermore, in this embodiment of the invention, the magnet assembly 11 is also maintained static for the magnetic medium 15, so that the magnet assembly 11 need not be reserved in the structural design of the disturbance generator 10. The movement space, in this way, is advantageous for reducing the volume of the disturbance generator 10. In other words, in the case where the volume of the disturbance generator 10 is maintained, the magnet assembly 11 is maintained static so that the structure of the disturbance generator 10 does not need to be reserved for the magnet. The movement space of the assembly 11 is thus advantageous for increasing the volumetric ratio of the magnet assembly 11 of the disturbance generator 10, thereby increasing the power generation efficiency of the disturbance generator 10.

Further, in this embodiment of the invention, the magnet assembly 11 has a first pole end 112 and a second pole end 113, wherein the first pole end 112 and the second pole end 113 are in the same direction Extending the magnet assembly 11, wherein one of the two ends 121 of the magnetic core 12 is simultaneously adjacent to the first magnetic pole 112 and the second magnetic pole 113, so that the end The magnetic gap 14 is formed between the portion 121 and the first pole end 112 of the magnet assembly 11, and between the end portion 121 and the second pole end 113 of the magnet assembly 11, respectively. Thus, by the movement of the magnetic medium 15 within the magnetic gap 14, a change in the medium within the magnetic gap 14 is formed such that a magnetic field within the magnetic gap 14 is responsive to the magnetic gap 14 The change of the medium changes, while the magnetic core 12 is looped around the coil 13 of the magnetic core 12 in response to a change in the magnetic field in the magnetic gap 14 corresponding to the end portion 121 thereof. The magnetic flux changes to generate electrical energy in the coil 13.

In particular, in order to further increase the power generation efficiency of the disturbance generator 10, in this embodiment of the invention, the magnetic medium 15 is arranged to be able to close the first in the magnetic gap 14 The position of the magnetic pole 112 and the end portion 121 and the position close to the second magnetic pole 113 and the end portion 121 are switched to be in the magnetic gap 14 by the magnetic medium 15 Moving, switching between one of the end portions 121 of the magnetic core 12 in a state of being connected to the first magnetic pole 112 and a state of being connected to the second magnetic pole 113, to The magnetic field in the magnetic core 12 can be reversely changed by the response of the magnetic core 12 to different magnetic poles, thereby increasing the variation of the magnetic flux of the coil 13 formed by the movement of the magnetic medium 15. The amount of change further increases the power generation efficiency of the disturbance generator 10.

It can be understood that the magnetic medium 15 can be brought close to the magnetic gap 14 to close the first magnetic pole 112 and the end 121 by the specific movement mode of the magnetic medium 15. Switching is made between a position close to turning on the second magnetic pole 113 and the end portion 121, wherein the manner of movement of the magnetic medium 15 is specific and not limited.

That is, a change in the magnetic flux of the coil 13 that can be formed by the movement of the magnetic medium 15 in the magnetic gap 14 can be caused by a specific movement of the magnetic medium 15 in the magnetic gap 14. Switching between one of the end portions 121 of the magnetic core 12 in a state of being connected to the first magnetic pole 112 and a state of being in contact with the second magnetic pole 113 to improve The amount of change in the change in the magnetic flux of the coil 13 formed by the movement of the magnetic medium 15, but the state in which one of the ends 121 of the magnetic core 12 is connected to the first magnetic pole 112 and The switching between the states in which the second magnetic poles 113 are turned on can be realized by various movement modes of the magnetic medium 15, which is not limited in the present invention.

As in some embodiments of the present invention, the magnetic medium 15 is arranged to adopt a linear reciprocating manner to be kept away from the position close to the first magnetic pole 112 and the end 121. Position of the second magnetic pole 113 and the end portion 121; and close to the first magnetic pole 112 and the ground when the position of the second magnetic pole 113 and the end portion 121 is closed The position of the end portion 121 is described.

In some embodiments of the present invention, the magnetic medium 15 is disposed in a rotational reciprocating manner to be rotationally rotated near a position at which the first magnetic pole 112 and the end portion 121 are turned on. Far from turning on the position of the second magnetic pole 113 and the end portion 121; and close to turning on the first magnetic pole when close to the position of turning on the second magnetic pole 113 and the end portion 121 112 and the position of the end portion 121.

That is to say, the disturbance generator 10 of the present invention is capable of converting mechanical energy into electrical energy in response to various motion modes, thereby avoiding the mechanical energy loss caused by converting different motion modes into a specific motion mode, thereby improving the The power generation efficiency of the magnetic generator 10 is described. Further, since the disturbance generator 10 can be adapted to convert mechanical energy into electrical energy in various motion modes, the disturbance generator 10 of the present invention can also be used for A corresponding electrical action is detected to generate a corresponding electrical signal to obtain information of the corresponding actuation action, such as a speed measurement for linear motion or rotational motion, by the electrical signal generated by the disturbance generator 10.

It can be understood that the first magnetic pole 112 and the second magnetic pole 113 are arranged to have different magnetic pole magnetic properties, that is, when the first magnetic pole 112 is magnetic pole of the S pole, the second The magnetic pole 113 has magnetic pole magnetic properties of the N pole, and when the first magnetic pole 112 is magnetic pole of the N pole, the second magnetic pole 113 has magnetic pole magnetism of the S pole, which is not limited in the present invention.

It is to be noted that, in this embodiment of the invention, the magnet assembly 11 further includes a magnetic conductive component 114, wherein the magnetic conductive component 114 is magnetically coupled to the permanent magnet 111 to The magnetic conductive component 114 forms the first magnetic pole 112 and the second magnetic pole 113, and is connected to the magnetic conductive of the permanent magnet 111 by the magnetic conductive component 114, so that the first magnetic pole 112 And a position at which the second magnetic pole 113 is formed matches a specific movement mode of the magnetic medium 15, that is, the magnetic conductive component 11 is disposed to be magnetically coupled to the permanent magnet 111, One of the two end portions 121 of the magnetic core 12 is formed in a positional relationship close to the first magnetic pole 112 and the second magnetic pole 113, respectively.

In detail, in this embodiment of the invention, the magnetic conductive component 114 includes a first magnetic conductive plate 1141 and a second magnetic conductive plate 1142, wherein the first magnetic conductive plate 1141 and the second conductive guide The magnetic plates 1142 are respectively magnetically connected to the two magnetic poles (ie, the S pole and the N pole) of the permanent magnet 111, that is, the two magnetic poles of the permanent magnet 111 are magnetically coupled to the first magnetic conductive plate 1141 and the One of the second magnetic conductive plates 1142, such that the first magnetic conductive plate 1141 forms the first magnetic pole 112, and the second magnetic conductive plate 1142 forms the second magnetic pole 113. Thus, the first magnetic pole 112 and the second magnetic pole 113 have different magnetic pole magnetic properties, and when one of the end portions 121 of the magnetic core 12 is moved by the magnetic medium 15 When switching between a state in which the first magnetic pole 112 is turned on and a state in which the second magnetic pole 113 is turned on, the direction of the magnetic field in the magnetic core 12 changes inversely, thereby The amount of change in the change in the magnetic flux of the coil 13 formed by the movement of the magnetic medium 15 is increased, thereby increasing the power generation efficiency of the disturbance generator 10.

That is, the magnetically conductive component 114 is in magnetic contact with the permanent magnet 111 such that the formation positions of the first magnetic pole 112 and the second magnetic pole 113 and the specific movement of the magnetic medium 15 The manners are matched, and when the positions of the two magnetic poles of the permanent magnet 111 can directly match the specific motion mode of the magnetic medium 15, the magnetic conductive component 114 may not be disposed, then the first The magnetic pole 112 and the second pole end 113 are respectively formed on two magnetic poles of the permanent magnet 111, such as when the permanent magnet 111 is provided as a U-shaped magnet, one of the ends of the magnetic core 12 121 can be directly adjacent to the two magnetic poles of the U-shaped magnet corresponding to both ends of the U-shaped magnet, that is, the two magnetic poles of the U-shaped magnet are the first magnetic pole 112 and the second magnetic pole 113, This is in accordance with the particular mode of motion of the magnetic medium 15, which is not limited by the invention.

It will be understood by those skilled in the art that in this embodiment of the invention, the magnetic core 12 and the magnet assembly 11 are close to each other to form the magnetic gap 14, and the movement of the magnetic medium 15 in the magnetic gap 14 When the medium in the magnetic gap 14 is changed, the magnetic field in the magnetic gap 14 changes in response to a change in the medium in the magnetic gap 14, and the magnetic field in the magnetic core 12 is responsive to the magnetic a change in the magnetic field in the gap 14 causes a change in the magnetic flux of the coil 13 that is looped over the core 12 to generate electrical energy in the coil 13, wherein the magnet assembly 11 The magnetic medium 15, the number of the magnetic core 12 and the coil 13 does not constitute a limitation of the present invention.

In order to further disclose the present invention, a perturbation generator 10A according to a modified embodiment of the previous embodiment of the present invention is illustrated with reference to FIGS. 2A and 2B of the accompanying drawings of the present invention, wherein FIG. 2A 2B and FIG. 2B respectively show a schematic structural view of the disturbance generator 10A in different states. Similarly, the disturbance generator 10A includes a magnet assembly 11A, a magnetic core 12A, and a coil 13A. The magnetic core 12A is disposed to be made of a magnetically permeable material and includes both end portions 121A, that is, a first end portion 1211A and a second end portion 1212A, wherein the first end portion 1211A and the second end portion 1212A are Provided to extend away from the magnetic core 12A at both ends of the magnetic core 12A, wherein the first end portion 1211A and the second end portion 1212A are respectively adjacent to the magnet assembly 11A. At least one magnetic gap 14A is formed between the magnet assembly 11A and the two end portions 121A of the magnetic core 12A, wherein the coil 13A is looped over the magnetic core 12A, such as in the magnetic gap 14A. When the magnetic field changes in response to a change in the medium in the magnetic gap 14A, the magnetic core 12A The magnetic flux of the coil 13A is changed in response to a change in the magnetic field within the magnetic gap 14A, thereby generating electrical energy at the coil 13A.

Different from the previous embodiment, in this embodiment of the invention, the magnet assembly 11A has two first magnetic pole ends 112A and two second magnetic pole ends 113A, wherein the first end portions 1211A and the two first portions respectively One of the magnetic pole ends 112A is adjacent to one of the two second magnetic poles 113A, and the second end portion 1212A is respectively opposite to the other of the two first magnetic poles 112A and the two The other of the two magnetic pole ends 113A is adjacent, such that the magnetic gap 14A is formed between the first end portion 1211A and the first magnetic pole end 112A and the second magnetic pole end 113A adjacent thereto, respectively. The magnetic gap 14A is formed between the second end portion 1212A and the first magnetic pole tip 112A and the second magnetic pole end 113A adjacent thereto.

Further, the disturbance generator 10A includes at least one magnetic medium 15A, wherein the magnetic medium 15A is disposed to be prepared using a magnetically permeable material to form a movement of the magnetic medium 15A in the magnetic gap 14A. a change in the medium within the magnetic gap 14A such that a magnetic field within the magnetic gap 14A changes in response to a change in the medium within the magnetic gap 14A, thereby causing the magnetic core 12A to respond to the magnetic gap 14A The change in the magnetic field inside changes the magnetic flux of the coil 13A to generate electric energy to the coil 13A.

Similarly, in this embodiment of the invention, the magnetic core 12A is maintained static for the magnetic medium 15A, so as to be able to maintain the coil 13A looped over the magnetic core 12A to be statically lowered. The requirement of the fatigue resistance of the coil 13A further enhances the stability of the disturbance generator 10A. In addition, the coil 13A is maintained static so that there is no need to reserve the movement space of the coil 13A in the structural design of the disturbance generator 10A, which is advantageous for reducing the volume of the disturbance generator 10A. In other words, in the case where the volume of the disturbance generator 10A is maintained, the coil 13A is maintained static so that the coil 13A does not need to be reserved in the structural design of the disturbance generator 10A. The movement space is such that it is advantageous to increase the volume ratio of the coil 13A of the disturbance generator 10A, thereby improving the power generation efficiency of the disturbance generator 10A.

In addition, the magnet assembly 11A is also maintained static for the magnetic medium 15A, so that the structural design of the disturbance generator 10A does not need to reserve the movement space of the magnet assembly 11A, which is advantageous for reduction. The volume of the disturbance generator 10A. In other words, in the case where the volume of the disturbance generator 10A is maintained, the magnet assembly 11A is maintained static so that the structure of the disturbance generator 10A does not need to be reserved in the structure design. The movement space of the assembly 11A is such that it is advantageous to increase the volume ratio of the magnet assembly 11A of the disturbance generator 10A, thereby improving the power generation efficiency of the disturbance generator 10A.

Specifically, in this embodiment of the invention, the number of the magnetic media 15A is two, that is, a first magnetic medium 151A and a second magnetic medium 152A, wherein the first magnetic medium 151A and the first The two magnetic medium 152A is disposed such that when the first magnetic medium 151A is in a position close to the first end portion 1211A and the first magnetic pole 112A close to the first end portion 1211A, The second magnetic medium 152A is synchronously located adjacent to the second end 1212A and the second magnetic pole 113A adjacent to the second end 1212A, and when the first magnetic medium 151A is located close to a position to turn on the first end portion 1211A and the second magnetic pole 113A adjacent to the first end portion 1211A, the second magnetic medium 152A is located in close proximity to be turned on. The second end portion 1212A and the position of the first magnetic pole 112A adjacent to the second end portion 1212A are described.

That is, in this embodiment of the invention, the magnetic medium 15A is arranged to connect the magnetic core 12A to the first magnetic pole 112A at the first end portion 1211A in a specific motion manner. And the second end portion 1212A is in a state of being connected to the second magnetic pole 113A, and the first end portion 1211A is connected to the second magnetic pole 113A and the second end portion 1212A is Switching between the states in which the first magnetic poles 112A are turned on to form a reverse switching of the magnetic field in the magnetic core 12A by the specific movement of the magnetic medium 15A, thereby improving the disturbance The power generation efficiency of the magneto generator 10A.

It can be understood that the magnetic core 12A can be connected to the first magnetic pole 112A at the first end portion 1211A and the second end portion by the specific movement mode of the magnetic medium 15A. a state in which the 1212A is in contact with the second magnetic pole 113A, and the first end portion 1211A is connected to the second magnetic pole 113A and the second end portion 1212A and the first magnetic pole 112A Switching is made between the states in which the phases are turned on, wherein the manner of movement of the magnetic medium 15A is specific and not limited.

That is, a change in the magnetic flux of the coil 13A that the magnetic medium 15A can move in the movement of the magnetic gap 14A, and a specific movement of the magnetic medium 15A in the magnetic gap 14A enables the a magnetic core 12A in a state in which the first end portion 1211A is in contact with the first magnetic pole 112A and the second end portion 1212A is in contact with the second magnetic pole 113A, and the first end The portion 1211A is switched between the state in which the second magnetic pole 113A is turned on and the second end portion 1212A is in contact with the first magnetic pole 112A to improve the movement of the magnetic medium 15A. The amount of change in the change in the magnetic flux of the coil 13A formed, but the core 12A is connected to the first pole end 112A at the first end portion 1211A and the second end portion 1212A is a state in which the second magnetic pole 113A is turned on, and the first end portion 1211A is connected to the second magnetic pole 113A and the second end portion 1212A is connected to the first magnetic pole 112A. The switching between the states can be realized by various movement modes of the magnetic medium 15A, and the present invention is not limited thereto.

As in some embodiments of the present invention, when the two first pole ends 112A are disposed adjacent to the first end portion 1211A and the second end portion 1212A on different sides of the magnetic core 12A, respectively The two magnetic poles 113A are disposed such that the first magnetic medium 151A and the first portion are respectively adjacent to the first end portion 1211A and the second end portion 1212A on different sides of the magnetic core 12A The two magnetic medium 152A can be disposed in a synchronous reciprocating linear reciprocating manner, when the first magnetic medium 151A approaches to turn on the first end portion 1211A and the first magnetic pole 112A, the second The magnetic medium 152A is synchronously approached in the same direction to turn on the second end portion 1212A and the second magnetic pole 113A; and when the first magnetic medium 151A approaches to turn on the first end portion 1211A and the At the second magnetic pole 112A, the second magnetic medium 152A is synchronously approached to open the second end 1212A and the first magnetic pole 112A.

In some embodiments of the present invention, likewise, when the two first magnetic poles 112A are disposed on the different sides of the magnetic core 12A, respectively, adjacent to the first end portion 1211A and the second end portion 1212A, While the two second magnetic poles 113A are disposed to be adjacent to the first end portion 1211A and the second end portion 1212A on different sides of the magnetic core 12A, the first magnetic medium 151A and the The second magnetic medium 152A can also be configured to be in a reciprocating manner of coaxial rotation, when the first magnetic medium 151A is rotationally brought close to turn on the first end portion 1211A and the first magnetic pole 112A The second magnetic medium 152A is synchronously rotated coaxially close to turn on the second end portion 1212A and the second magnetic pole 113A; and when the first magnetic medium 151A is rotationally close to be turned on At the first end portion 1211A and the second magnetic pole 113A, the second magnetic medium 152A is rotationally synchronized to close the second end portion 1212A and the first magnetic pole 112A.

That is to say, the disturbance generator 10A of the present invention is capable of converting mechanical energy into electrical energy in response to various motion modes, thereby avoiding the mechanical energy loss caused by converting different motion modes into a specific motion mode, thereby improving the The power generation efficiency of the magnetic generator 10A is described. Further, since the disturbance generator 10A can be adapted to convert mechanical energy into electrical energy in various motion modes, the disturbance generator 10A of the present invention can also be used for A corresponding electrical action is detected to generate a corresponding electrical signal to obtain information of the corresponding actuation action, such as a speed measurement for linear motion or rotational motion, by the electrical signal generated by the disturbance generator 10A.

It can be understood that the first magnetic pole 112A and the second magnetic pole 113A are arranged to have different magnetic pole magnetic properties, that is, when the first magnetic pole 112A is magnetic pole of the S pole, the second The magnetic pole 113A is magnetic pole magnetic on the N pole, and when the first magnetic pole 112A is magnetic pole of the N pole, the second magnetic pole 113A is magnetic pole of the S pole, which is not limited in the present invention.

In particular, in this embodiment of the invention, the two first pole ends 112A are disposed adjacent to the first end 1211A and the second end 1212A on the same side of the core 12A, respectively. At the same time, the two second magnetic poles 113A are disposed adjacent to the first end portion 1211A and the second end portion 1212A on the same side of the magnetic core 12A. The first magnetic medium 151A and the second magnetic medium 152A are disposed to perform a rocking-type reciprocating motion with a point on a line connecting the first magnetic medium 151A and the second magnetic medium 152A as an axis. When the first magnetic medium 151A approaches to turn on the first end portion 1211A and the first magnetic pole 112A adjacent to the first end portion 1211A, the second magnetic medium 152A is synchronously reversed Proximate to close the second end 1212A and the second pole end 113A adjacent to the second end 1212A, and when the first magnetic medium 151A approaches to turn on the first end When the portion 1211A and the second magnetic pole 113A are adjacent to the first end portion 1211A, the second magnetic medium 153A is synchronously reversely close to turn on the second end portion 1212A and the first portion The first pole end 112A is adjacent to the two end portions 1212A.

It can be understood that when the two first magnetic poles 112A are disposed on the same side of the magnetic core 12A, respectively, close to the first end portion 1211A and the second end portion 1212A, The two magnetic poles 113A are disposed such that the first magnetic medium 151A and the second magnetic medium are adjacent to the first end portion 1211A and the second end portion 1212A on the same side of the magnetic core 12A, respectively. 152A can also be configured to adopt a reciprocating motion of coaxial rotation, that is, the first magnetic medium 151A turns on the first end portion 1211A and the first magnetic body close to the first end portion 1211A. When the position of the pole 112A is rotationally approached to turn on the first end portion 1211A and the second pole end 113A adjacent to the first end portion 1211A, the second magnetic medium 152A is turned on. The position of the second end portion 1212A and the second magnetic pole 113A adjacent to the second end portion 1212A are synchronously rotated coaxially to close the second end portion 1212A and the second portion The first pole end 112A is adjacent to the end portion 1212A.

In detail, in this embodiment of the invention, the magnet assembly 11A includes two permanent magnets 111A and two magnetically conductive components 114A, wherein the two magnetically conductive components 114A are disposed to respectively conduct magnetically with the two permanent magnets 111A. Connecting, that is, two of the permanent magnets 111A are respectively connected with one of the two magnetic conductive components 114A to provide a magnetic field environment for the disturbance generator 10A through the two permanent magnets 111A, and by the two The magnetically conductive component 114A is magnetically coupled to the two permanent magnets 111A, and the first magnetic pole 112A and the second magnetic pole 113A are formed in each of the magnetic conductive components 114A.

Further, in this embodiment of the invention, the magnetic conductive component 114A includes a first magnetic conductive plate 1141A and a second magnetic conductive plate 1142A, wherein the first magnetic conductive plate 1141A and the second conductive guide The magnetic plates 1142A are magnetically connected to the two magnetic poles (ie, the S pole and the N pole) of the permanent magnet 111A, that is, the two magnetic poles of the permanent magnet 111A are magnetically coupled to the first magnetic conductive plate 1141A and the One of the second magnetic conductive plates 1142A, such that the first magnetic conductive plate 1141A forms the first magnetic pole 112A, and the second magnetic conductive plate 1142A forms the second magnetic pole 113A. Thus, the first magnetic pole 112A and the second magnetic pole 113A have different magnetic pole magnetic properties, and when the magnetic core 12A is connected to the first magnetic pole 112A at the first end portion 1211A and a state in which the second end portion 1212A is in contact with the second magnetic pole 113A, and the first end portion 1211A is connected to the second magnetic pole 113A and the second end portion 1212A is When the state in which the first magnetic pole 112A is turned on is switched, the direction of the magnetic field in the magnetic core 12A is reversely changed, thereby improving the coil 13A formed by the movement of the magnetic medium 15A. The amount of change in the change in the magnetic flux further increases the power generation efficiency of the disturbance generator 10A.

In comparison with the previous embodiment, those skilled in the art will further understand that the number of the permanent magnet 111A, the magnetic medium 15A, the magnetic core 12A, and the coil 13A does not constitute a limitation of the present invention.

Referring to Figure 3 of the accompanying drawings of the present invention, a three-dimensional structure of a perturbation generator 10B according to a further variation of the previous embodiment of the present invention is illustrated, wherein the disturbance generator 10B includes a magnet The assembly 11B, a magnetic core 12B, and a coil 13B, wherein the magnetic core 12B is disposed to be made of a magnetically permeable material and includes both end portions 121B, wherein the two end portions 121B of the magnetic core 12B are respectively The magnet assembly 11B is adjacent to form at least one magnetic gap 14B between the magnet assembly 11B and the two end portions 121B of the magnetic core 12B, wherein the coil 13B is looped over the magnetic core 12B. If the magnetic field in the magnetic gap 14B changes in response to a change in the medium in the magnetic gap 14B, the magnetic core 12B causes the coil to respond to a change in the magnetic field in the magnetic gap 14B. The magnetic flux of 13B is changed to generate electric energy to the coil 13B.

Similarly, in this embodiment of the invention, the magnet assembly 11B has two first magnetic pole ends 112B and two second magnetic pole ends 113B, and the two end portions 121B of the magnetic core 12B, that is, a first end a portion 1211B and a second end portion 1212B, wherein the first end portion 1211B and the second end portion 1212B are disposed from the opposite ends of the magnetic core 12B in the radial direction of the magnetic core 12B, respectively Extending, wherein the first end portion 1211B is adjacent to one of the two first magnetic poles 112B and one of the two second magnetic poles 113B, respectively, and the second end portion 1212B is respectively The other of the two first magnetic poles 112B and the other of the two second magnetic poles 113B are adjacent, such that the first end portion 1211B and the first magnetic pole end 112B adjacent thereto The magnetic gap 14B is formed between the second magnetic pole 113B and the second magnetic pole 113B, and the second end portion 1212B and the first magnetic pole 112B and the second magnetic pole 113B are formed respectively. The magnetic gap 14B.

In particular, in this embodiment of the invention, wherein the first end portion 1211B and the second end portion 1212B are disposed from the opposite ends of the magnetic core 12B in the radial direction of the magnetic core 12B, respectively. The directions extend in the same direction to dispose the magnet assembly 11B between the first end portion 1211B and the second end portion 1212B in the radial space of the magnetic core 12B, thus facilitating shortening of the The length of the disturbance generator 10B in the direction of the core 12B.

Further, the disturbance generator 10B includes at least one magnetic medium 15B, wherein the magnetic medium 15B is disposed to be prepared using a magnetically permeable material to form a movement of the magnetic medium 15B in the magnetic gap 14B. a change in the medium within the magnetic gap 14B such that a magnetic field within the magnetic gap 14B changes in response to a change in the medium within the magnetic gap 14B, thereby causing the magnetic core 12B to respond to the magnetic gap 14B The change of the magnetic field inside changes the magnetic flux of the coil 13B to generate electric energy to the coil 13B.

Similarly, in this embodiment of the invention, the magnetic core 12B is maintained static for the magnetic medium 15B, so as to be able to maintain the coil 13B looped over the magnetic core 12B to be statically lowered. The requirement of the fatigue resistance of the coil 13B further enhances the stability of the disturbance generator 10B. In addition, the coil 13B is maintained static so that there is no need to reserve the movement space of the coil 13B in the structural design of the disturbance generator 10B, which is advantageous for reducing the volume of the disturbance generator 10B. In other words, in the case where the volume of the disturbance generator 10B is maintained, the coil 13B is maintained static so that the coil 13B does not need to be reserved in the structural design of the disturbance generator 10B. The movement space is such that it is advantageous to increase the volume ratio of the coil 13B of the disturbance generator 10B, thereby improving the power generation efficiency of the disturbance generator 10B.

In addition, the magnet assembly 11B is also maintained static for the magnetic medium 15B, so that the structural design of the disturbance generator 10B does not need to reserve the movement space of the magnet assembly 11B, which is advantageous for reduction. The volume of the disturbance generator 10B. In other words, in the case where the volume of the disturbance generator 10B is maintained, the magnet assembly 11B is maintained static so that the structure of the disturbance generator 10B does not need to be reserved in the structure design. The movement space of the assembly 11B is such that it is advantageous to increase the volume ratio of the magnet assembly 11B of the disturbance generator 10B, thereby improving the power generation efficiency of the disturbance generator 10B.

Further referring to FIG. 4A and FIG. 4B of the accompanying drawings of the present invention, a schematic structural view of the peristaltic generator 10B according to this embodiment of the present invention in different states is shown. In an embodiment, the number of the magnetic media 15B is two, that is, a first magnetic medium 151B and a second magnetic medium 152B, wherein the first magnetic medium 151B and the second magnetic medium 152B are disposed to be The second magnetic medium 151B is synchronized when the first magnetic medium 151B is in a position close to the first end portion 1211B and the first magnetic pole 112B adjacent to the first end portion 1211B. Located adjacent to the second end 1212B and the second pole end 113B adjacent to the second end 1212B, and when the first magnetic medium 151B is located close to When the first end portion 1211B and the second magnetic pole 113B are adjacent to the first end portion 1211B, the second magnetic medium 152B is synchronously located to close the second end portion 1212B and The second end portion 1212B is adjacent to the position of the first magnetic pole 112B.

That is, in this embodiment of the invention, the magnetic medium 15B is arranged to connect the magnetic core 12B to the first magnetic pole 112B at the first end portion 1211B in a specific motion manner. And the second end portion 1212B is in a state of being connected to the second magnetic pole 113B, and the first end portion 1211B is connected to the second magnetic pole 113B and the second end portion 1212B is Switching between the states in which the first magnetic poles 112B are turned on to form a reverse switching of the magnetic field in the magnetic core 12B by the specific movement of the magnetic medium 15B, thereby improving the disturbance The power generation efficiency of the magneto generator 10B.

It can be understood that the magnetic core 12B can be connected to the first magnetic pole 112B at the first end portion 1211B and the second end portion by the specific movement mode of the magnetic medium 15B. a state in which the 1212B is in contact with the second magnetic pole 113B, and the first end portion 1211B is connected to the second magnetic pole 113B and the second end portion 1212B and the first magnetic pole 112B Switching is made between the states in which the phases are turned on, wherein the manner of movement of the magnetic medium 15B is specific and not limited.

That is, a change in the magnetic flux of the coil 13B that the magnetic medium 15B can move in the magnetic gap 14B, and a specific movement of the magnetic medium 15B in the magnetic gap 14B enables the a state in which the magnetic core 12B is connected to the first end portion 1211B and the first magnetic pole 112B, and the second end portion 1212B is in contact with the second magnetic pole 113B, and the first end The portion 1211B is switched between the state in which the second magnetic pole 113B is turned on and the second end portion 1212B is in contact with the first magnetic pole 112B to improve the movement of the magnetic medium 15B. The amount of change in the change in the magnetic flux of the coil 13B formed, but the core 12B is connected to the first pole end 112B at the first end portion 1211B and the second end portion 1212B is a state in which the second magnetic pole 113B is turned on, and the first end portion 1211B is connected to the second magnetic pole 113B and the second end portion 1212B is connected to the first magnetic pole 112B. The switching between the states can be realized by various movement modes of the magnetic medium 15B, and the present invention is not limited thereto. .

In other words, the perturbation generator 10B of the present invention is capable of converting mechanical energy into electrical energy in response to various motion modes, thereby avoiding the mechanical energy loss caused by converting different motion modes into a specific motion mode, thereby improving The power generation efficiency of the disturbance generator 10B, further, the disturbance generator 10B of the present invention can also be used because the disturbance generator 10B can be adapted to convert mechanical energy into electrical energy in a variety of motion modes. Corresponding electrical signals are generated to detect different actuation actions to obtain information of corresponding actuation actions, such as speed measurement for linear motion or rotational motion, by electrical signals generated by the disturbance generator 10B.

It can be understood that the first magnetic pole 112B and the second magnetic pole 113B are arranged to have different magnetic pole magnetic properties, that is, when the first magnetic pole 112B is magnetic pole of the S pole, the second The magnetic pole 113B is magnetic pole magnetic on the N pole, and when the first magnetic pole 112B is magnetic pole of the N pole, the second magnetic pole 113B is magnetic pole of the S pole, which is not limited in the present invention.

In particular, in this embodiment of the invention, the magnet assembly 11B is disposed between the first end portion 1211B and the second end portion 1212B, and the wires of the two first magnetic pole ends 112B are connected. Intersecting with a line connecting the two second magnetic poles 113B, wherein the first magnetic medium 151B and the second magnetic medium 152B are disposed in a synchronous reciprocating linear reciprocating manner, in the first magnetic medium When the 151B is close to turn on the first end portion 1211B and the first magnetic pole 112B, the second magnetic medium 152B is synchronously approached to close the second end portion 1212B and the second magnetic portion. An extreme 113B; and when the first magnetic medium 151B approaches to turn on the first end 1211B and the second magnetic pole 112B, the second magnetic medium 152B is synchronously approached to turn on the The second end portion 1212B and the first magnetic pole end 112B.

It can be understood that the first magnetic medium 151B and the second magnetic medium 152B can also be configured to adopt a coaxial rotating reciprocating manner, that is, the first magnetic medium 151B is turned on at the first end. a portion 1211B and a position of the first pole end 112B adjacent to the first end portion 1211B are rotatably brought close to close the first end portion 1211B and the first end portion 1211B When the second magnetic pole 113B is described, the second magnetic medium 152B is coaxially synchronized with the position of the second end portion 1212B and the second magnetic pole 113B close to the second end portion 1212B. Rotatingly approaching to open the second end 1212B and the first pole end 112B adjacent the second end 1212B.

In detail, in this embodiment of the invention, the magnet assembly 11B includes two permanent magnets 111B, wherein the two permanent magnets 111B are disposed between the first end portion 1211B and the second end portion 1212B. And the two magnetic poles of each of the permanent magnets 111B are respectively adjacent to the first end portion 1211B and the second end portion 1212B, that is, each of the permanent magnets 111B forms a first magnetic field at two magnetic pole ends thereof. The extreme 112B and a second magnetic pole 113B, in addition, the first magnetic pole 112B adjacent to the first end portion 1211B and the second magnetic pole 113B adjacent to the second end portion 1212B are identical The permanent magnets 111B are formed, that is, the first magnetic poles 112B and the second magnetic poles 113B corresponding to the end portions 121B are formed by different permanent magnets 111B, so that the two The line connecting the first magnetic pole 112B and the line connecting the two second magnetic poles 113B intersect, so that the first magnetic medium 151B and the second magnetic medium 152B can be reciprocated in a synchronous manner in the same direction. Achieving the magnetic core 12B at the first end portion 1211B and the first magnetic body a state in which the terminal 112B is turned on and the second end portion 1212B is in contact with the second magnetic pole 113B, and the first end portion 1211B is connected to the second magnetic pole 113B and the first Switching between the state in which the two end portions 1212B are in contact with the first magnetic pole end 112B.

In comparison with the previous embodiment, those skilled in the art will further understand that the perturbation generator 10B of the present invention forms the magnetic medium 15B by the magnetic core 12B and the magnet assembly 11B being close to each other. The movement of the magnetic gap 14B causes the medium in the magnetic gap 14B to change while the magnetic field in the magnetic gap 14B changes in response to a change in the medium in the magnetic gap 14B, and the magnetic core 12B The magnetic field changes in response to a change in the magnetic field in the magnetic gap 14B, so that the magnetic flux that is looped around the coil 13B of the magnetic core 12B changes, thereby generating electrical energy in the coil 13B. The structure of the magnetic core 12B and the magnet assembly 11B has various embodiments according to the embodiments of the present invention, and the present invention is not limited thereto.

Referring to Figures 5 and 6 of the drawings of the present invention, a perturbation generator 10B' according to a modified embodiment of the previous embodiment of the present invention is illustrated, wherein Figures 5 and 6 respectively show The schematic diagram of the three-dimensional structure and the working principle of the disturbance generator 10B'. The disturbance generator 10B' includes a magnet assembly 11B', a magnetic core 12B', and a coil 13B', wherein the magnetic core 12B' is disposed to be made of a magnetically permeable material and includes both end portions 121B', Wherein the two end portions 121B' of the magnetic core 12B' are respectively adjacent to the magnet assembly 11B', so that the magnet assembly 11B' and the two end portions 121B' of the magnetic core 12B' are Forming at least one magnetic gap 14B', wherein the coil 13B' is looped over the magnetic core 12B', such as when the magnetic field in the magnetic gap 14B' is responsive to changes in the medium within the magnetic gap 14B' When a change occurs, the magnetic core 12B' causes the magnetic flux of the coil 13B' to be changed in response to a change in the magnetic field in the magnetic gap 14B' to generate electric energy in the coil 13B'.

In particular, in this embodiment of the invention, the magnet assembly 11B' has a first magnetic pole 112B' and a second magnetic pole 113B', and the two end portions 121B' of the magnetic core 12B', That is, a first end portion 1211B' and a second end portion 1212B', wherein the first end portion 1211B' and the second end portion 1212B' are disposed from the ends of the magnetic core 12B', respectively. The radial direction of the magnetic core 12B' extends in the same direction, wherein the first end 1211B' and the second end 1212B' are respectively disposed adjacent to the first magnetic pole 112B' and the Second magnetic pole 113B'. Specifically, the magnet assembly 11B' is disposed between the first end portion 1211B' and the second end portion 1212B' in a radial space of the magnetic core 12B', and the first end a connecting direction between the portion 1211B' and the second end portion 1212B' intersects with a connecting direction between the first magnetic pole 112B' and the second magnetic pole 113B', thus forming the first The one end portion 1211B' and the second end portion 1212B' are respectively close to the positional relationship of the first magnetic pole end 112B' and the second magnetic pole end 113B', respectively, and the first end portion 1211B' is respectively Forming the magnetic gap 14B' with the first magnetic pole 112B' and the second magnetic pole 113B', the second end portion 1212B' and the first magnetic pole 112B' and the first The magnetic gap 14B' is formed between the two magnetic pole ends 113B'.

It is worth mentioning that in this embodiment of the invention, the first end portion 1211B' and the second end portion 1212B' are disposed from the two ends of the magnetic core 12B' respectively. The radial direction of the magnetic core 12B' extends in the same direction to dispose the magnet assembly 11B' in the radial space of the magnetic core 12B' at the first end portion 1211B' and the second end portion 1212B. In between, it is advantageous to shorten the length of the disturbance generator 10B' in the direction of the core 12B'.

Further, in this embodiment of the invention, the disturbance generator 10B' includes at least one magnetic medium 15B', wherein the magnetic medium 15B' is disposed to be prepared using a magnetically permeable material to Movement of the medium 15B' in the magnetic gap 14B' forms a change in the medium within the magnetic gap 14B' such that a magnetic field within the magnetic gap 14B' occurs in response to a change in the medium within the magnetic gap 14B' The change, in turn, causes the magnetic core 12B' to generate electrical energy at the coil 13B' in response to a change in the magnetic field within the magnetic gap 14B' that changes the magnetic flux of the coil 13B'.

Similarly, in this embodiment of the invention, the magnetic core 12B' is maintained static for the magnetic medium 15B' such that the coil 13B' that is looped over the magnetic core 12B' is stationary. The requirement for the fatigue resistance of the coil 13B' is lowered, thereby enhancing the stability of the disturbance generator 10B'. In addition, the coil 13B' is maintained static so that there is no need to reserve the movement space of the coil 13B' in the structural design of the disturbance generator 10B', thus facilitating reduction of the disturbance generator 10B' volume of. In other words, in the case where the volume of the disturbance generator 10B' is maintained, the coil 13B' is maintained static, so that the structure design of the disturbance generator 10B' does not need to be reserved. The movement space of the coil 13B' is such that it is advantageous to increase the volume ratio of the coil 13B' of the disturbance generator 10B', thereby improving the power generation efficiency of the disturbance generator 10B'.

In addition, the magnet assembly 11B' is also maintained static for the magnetic medium 15B', so that there is no need to reserve the movement space of the magnet assembly 11B' in the structural design of the disturbance generator 10B'. It is advantageous to reduce the volume of the disturbance generator 10B'. In other words, in the case where the volume of the disturbance generator 10B' is maintained, the magnet assembly 11B' is maintained static so that the structure design of the disturbance generator 10B' does not need to be reserved. The movement space of the magnet assembly 11B' is such that it is advantageous to increase the volume ratio of the magnet assembly 11B' of the disturbance generator 10B', thereby improving the power generation efficiency of the disturbance generator 10B'.

Further, in this embodiment of the invention, the number of the magnetic media 15B' is two, that is, a first magnetic medium 151B' and a second magnetic medium 152B', wherein the first magnetic medium 151B' And the second magnetic medium 152B' is disposed to be when the first magnetic medium 151B' is in a position to close the first end portion 1211B' and the first magnetic pole 112B' The second magnetic medium 152B' is in a position close to the second end 1212B' and the second magnetic pole 113B', and when the first magnetic medium 151B' is in proximity to turn on the first end At the position of the portion 1211B' and the second magnetic pole 113B', the second magnetic medium 152B' is in a position close to the second end portion 1212B' and the first magnetic pole 112B'.

That is, in this embodiment of the invention, the magnetic medium 15B' is arranged to move the magnetic core 12B' to the first end portion 1211B' and the first magnetic pole 112B in a specific motion manner. a state in which the phase is turned on and the second end portion 1212B' is in contact with the second magnetic pole 113B', and the first end portion 1211B' is connected to the second magnetic pole 113B' and Switching between the state in which the second end portion 1212B' is in contact with the first magnetic pole 112B' to form the magnetic core 12B' by the specific movement of the magnetic medium 15B' The reverse switching of the magnetic field further increases the power generation efficiency of the disturbance generator 10B'.

It can be understood that the magnetic core 12B' can be connected to the first magnetic pole 112B' at the first end portion 1211B' by the specific movement mode of the magnetic medium 15B' and the a state in which the second end portion 1212B' is in contact with the second magnetic pole 113B', and the first end portion 1211B' is connected to the second magnetic pole 113B' and the second end portion 1212B The switching is made between the states in which the first magnetic poles 112B' are connected, wherein the manner of movement of the magnetic medium 15B' is specific and not limited.

That is, the magnetic medium 15B' can be formed by the movement of the magnetic gap 14B' to change the magnetic flux of the coil 13B', and the specific movement of the magnetic medium 15B' to the magnetic gap 14B' The manner of enabling the magnetic core 12B' to be connected to the first magnetic pole 112B' at the first end portion 1211B' and the second end portion 1212B' to the second magnetic pole 113B' a state of being connected between the first end portion 1211B' and the second magnetic pole 113B' and the second end portion 1212B' being in contact with the first magnetic pole 112B' Switching is performed to increase the amount of change in the change in the magnetic flux of the coil 13B' formed by the movement of the magnetic medium 15B', but the core 12B' is at the first end portion 1211B' and the a state in which the first magnetic pole 112B' is turned on and the second end portion 1212B' is in contact with the second magnetic pole 113B', and the first end portion 1211B' and the second magnetic pole 113B The switching between the state in which the phase is turned on and the second end portion 1212B' is in contact with the first magnetic pole 112B' can be Magnetic media 15B 'plurality of motion realized, the present invention is not limited to this.

In other words, the perturbation generator 10B' of the present invention is capable of converting mechanical energy into electrical energy in response to various motion modes to avoid the mechanical energy loss caused by converting different motion modes into a specific motion mode. The power generation efficiency of the disturbance generator 10B' is increased. Further, since the disturbance generator 10B' can be adapted to convert mechanical energy into electrical energy in various motion modes, the disturbance generator 10B' of the present invention It can also be used to detect different actuation actions to generate corresponding electrical signals to obtain information of corresponding actuation actions, such as for linear motion or rotational motion, by electrical signals generated by the disturbance generator 10B'. Speed measurement.

It can be understood that the first magnetic pole 112B' and the second magnetic pole 113B' are arranged to have different magnetic pole magnetic properties, that is, when the first magnetic pole 112B' is magnetic pole of the S pole. The second magnetic pole 113B′ is magnetic pole magnetic of the N pole, and when the first magnetic pole 112B′ is magnetic pole of the N pole, the second magnetic pole 113B′ is magnetic pole of the S pole, and the present invention is This is not limited.

In particular, in this embodiment of the invention, the first magnetic medium 151B' and the second magnetic medium 152B' are arranged in a coaxially oscillating motion, ie, the first magnetic medium 151B' and An axis between the second magnetic media 152B' is an axis, and when the first magnetic medium 151B' is turned on at the position of the first end portion 1211B' and the first magnetic pole 112B' When the shaft is pivotally close to turn on the first end portion 1211B' and the second magnetic pole 113B', the second magnetic medium 152B' is turned on to the second end portion 1212B' and The positional synchronization of the second magnetic pole 113B' is coaxially rotated close to turn on the second end 1212B' and the first magnetic pole 112B'.

In detail, in this embodiment of the invention, the disturbance generator 10B' further includes a link 17B', wherein the first magnetic medium 151B' and the second magnetic medium 152B' are respectively disposed on Both ends of the connecting rod 17B' are connected to the first magnetic medium 151B' and the second magnetic medium 152B' by the connecting rod 17B', so that the first magnetic medium 151B' and The second magnetic medium 152B' can be driven to oscillate coaxially with a point on the link 17B' as a fulcrum.

Further, in this embodiment of the invention, the magnet assembly 11B' includes a permanent magnet 111B' and a magnetically conductive component 114B' to provide the peristaltic generator 10B' through the permanent magnet 111B'. a magnetic field environment, wherein the permanent magnet 111B' is disposed between the first end portion 1211B' and the second end portion 1212B' in a radial space of the magnetic core 12B', wherein the magnetic conductive component 114B' is magnetically coupled to the permanent magnet 111B' to form the first magnetic pole 112B' and the second magnetic pole 113B' by the magnetic conductive component 114B', and the magnetic conductive component is 114B' is in magnetic communication with the permanent magnet 111B' such that the formation positions of the first magnetic pole 112B' and the second magnetic pole 113B' match the specific movement manner of the magnetic medium 15B' That is, the magnetically permeable component 114B' is configured to be magnetically coupled to the permanent magnet 111B' to form the first end portion 1211B' and the second end portion 1212B' simultaneously adjacent to each other. a positional relationship of the first magnetic pole 112B' and the second magnetic pole 113B'.

In detail, in this embodiment of the invention, the magnetic conductive component 114B' includes a first magnetic conductive plate 1141B' and a second magnetic conductive plate 1142B', wherein the first magnetic conductive plate 1141B' and the The second magnetic conductive plates 1142B' are respectively magnetically connected to the two magnetic poles (ie, the S pole and the N pole) of the permanent magnet 111B', that is, the two magnetic poles of the permanent magnet 111B' are magnetically connected to the first One of the magnetic conductive plate 1141B' and the second magnetic conductive plate 1142B', such that the first magnetic conductive plate 1141B' forms the first magnetic pole 112B', and the second magnetic conductive plate 1142B 'The second magnetic pole 113B' is formed. In particular, the first magnetic conductive plate 1141B' and the second magnetic conductive plate 1142B' are respectively adjacent to the first end portion 1211B' and the second end portion 1212B', that is, the permanent magnet 111B. 'The first magnetically permeable plate 1141B' and the second magnetically permeable plate 1142B' respectively disposed at the two magnetic pole ends of the permanent magnet 111B' form an "H" shaped magnet assembly 11B', The left and right sides of the "H" shape are formed by the first magnetic conductive plate 1141B' and the second magnetic conductive plate 1142B', so that the upper and lower ends of the "H" shape are respectively The first end portion 1211B' and the second end portion 1212B' are adjacent to each other, so that the first end portion 1211B' and the second end portion 1212B' are respectively formed close to the first magnetic pole end 112B' A positional relationship with the second magnetic pole 113B'.

In comparison with the previous embodiment, those skilled in the art will further understand that the perturbation generator 10B' of the present invention is in close proximity to the magnet assembly 11B' by the magnetic core 15B' through the magnetic medium 15B'. The movement of the magnetic gap 14B' is formed such that the medium within the magnetic gap 14B' changes while the magnetic field within the magnetic gap 14B' changes in response to changes in the medium within the magnetic gap 14B'. And the magnetic field in the magnetic core 12B' changes in response to a change in the magnetic field in the magnetic gap 14B', so that the magnetic flux of the coil 13B' looped around the magnetic core 12B' changes. Further, the coil 13B' generates electric energy, and the structure of the magnetic core 12B' and the magnet assembly 11B' has various embodiments according to the embodiment of the present invention, which is not limited by the present invention.

Referring to Figure 7 of the accompanying drawings of the present invention, a perturbation generator 10B" according to a further modified embodiment of the above-described variant embodiment of the present invention is illustrated, wherein Figure 7 mainly illustrates the disturbance. Schematic diagram of the three-dimensional structure of the magnet generator 10B". Similarly, the disturbance generator 10B" includes a magnet assembly 11B", a magnetic core 12B", and a coil 13B", wherein the magnetic core 12B" is configured to be made of a magnetically permeable material and includes both ends 121B", wherein the two end portions 121B" of the magnetic core 12B" are respectively adjacent to the magnet assembly 11B" to the two ends of the magnet assembly 11B" and the magnetic core 12B" Forming at least one magnetic gap 14B" between 121B", wherein the coil 13B" is looped over the magnetic core 12B", such as when a magnetic field within the magnetic gap 14B" is responsive to the magnetic gap 14B" When the change in the medium changes, the magnetic core 12B" changes the magnetic flux of the coil 13B" in response to a change in the magnetic field within the magnetic gap 14B" to generate electrical energy for the coil 13B".

Further, the magnet assembly 11B" has a first magnetic pole 112B" and a second magnetic pole 113B", and the two end portions 121B" of the magnetic core 12B", that is, a first end portion 1211B" and a second end portion 1212B", wherein the first end portion 1211B" and the second end portion 1212B" are disposed in radial directions from the ends of the magnetic core 12B" to the magnetic core 12B", respectively The directions extend in the same direction, wherein the first end portion 1211B" and the second end portion 1212B" are disposed to be adjacent to the first magnetic pole tip 112B" and the second magnetic pole tip 113B", respectively.

Unlike the previous embodiment, in this embodiment of the invention, the magnet assembly 11B" is disposed in the extending direction of the first end portion 1211B" and the second end portion 1212B" respectively The first end portion 1211B" is adjacent to the second end portion 1212B", and a wiring direction between the first end portion 1211B" and the second end portion 1212B" is the same as the first magnetic pole 112B The line direction between the "and the second pole end 113B" intersects, thus forming the first end portion 1211B" and the second end portion 1212B" simultaneously adjacent to the first pole end 112B, respectively" a positional relationship with the second magnetic pole 113B" and forming the magnetic gap 14B between the first end portion 1211B" and the first magnetic pole 112B" and the second magnetic pole 113B", respectively The second end portion 1212B" forms the magnetic gap 14B" between the first magnetic pole tip 112B" and the second magnetic pole tip 113B", respectively.

Similarly, the disturbance generator 10B" includes at least one magnetic medium 15B", wherein the magnetic medium 15B" is disposed to be prepared using a magnetically permeable material to the magnetic gap 14B by the magnetic medium 15B" The movement of the medium forms a change in the medium within the magnetic gap 14B" such that the magnetic field within the magnetic gap 14B" changes in response to a change in the medium within the magnetic gap 14B", thereby causing the magnetic core 12B The magnetic flux of the coil 13B" is changed to generate electric energy to the coil 13B" in response to a change in the magnetic field within the magnetic gap 14B".

Further, the magnetic core 12B" is maintained static for the magnetic medium 15B" such that the coil 13B" that is looped over the magnetic core 12B" is statically lowered against the coil 13B" The requirement for fatigue resistance further enhances the stability of the spoiler generator 10B". In addition, the coil 13B" is maintained static so that the structural design of the disturbance generator 10B" does not need to reserve the movement space of the coil 13B", thus facilitating the reduction of the disturbance generator 10B" volume of. In other words, in the case where the volume of the disturbance generator 10B" is maintained, the coil 13B" is maintained static so that the structure design of the disturbance generator 10B" does not need to be reserved. The movement space of the coil 13B" is such that it is advantageous to increase the volume ratio of the coil 13B" of the disturbance generator 10B", thereby improving the power generation efficiency of the disturbance generator 10B".

In addition, the magnet assembly 11B" is also maintained static for the magnetic medium 15B", so that there is no need to reserve the movement space of the magnet assembly 11B" in the structural design of the disturbance generator 10B". It is advantageous to reduce the volume of the disturbance generator 10B". In other words, the magnet assembly 11B" is maintained static while maintaining the volume of the disturbance generator 10B" unchanged. In the structural design of the disturbance generator 10B", there is no need to reserve the movement space of the magnet assembly 11B", so that it is advantageous to increase the volume ratio of the magnet assembly 11B" of the disturbance generator 10B". Further, the power generation efficiency of the disturbance generator 10B" is increased.

Similarly, the number of the magnetic media 15B" is two, that is, a first magnetic medium 151B" and a second magnetic medium 152B", wherein the first magnetic medium 151B" and the second magnetic medium 152B" When the first magnetic medium 151B" is in a position to close the first end portion 1211B" and the first magnetic pole 112B", the second magnetic medium 152B" is placed close to Passing the position of the second end portion 1212B" and the second magnetic pole 113B", and when the first magnetic medium 151B" is in proximity to turn on the first end portion 1211B" and the second magnetic In the position of the extreme 113B", the second magnetic medium 152B" is in a position close to the second end portion 1212B" and the first magnetic pole 112B".

That is, in this embodiment of the invention, the magnetic medium 15B" is arranged to drive the magnetic core 12B" to the first end portion 1211B" and the first magnetic pole 112B in a specific motion manner. a state in which the phase is turned on and the second end portion 1212B" is in contact with the second magnetic pole 113B", and the first end portion 1211B" is connected to the second magnetic pole 113B" and The state in which the second end portion 1212B" is in contact with the first magnetic pole 112B" is switched to form the magnetic core 12B" by the specific movement of the magnetic medium 15B" The reverse switching of the magnetic field further increases the power generation efficiency of the disturbance generator 10B".

It can be understood that the magnetic core 12B" can be connected to the first end portion 1211B" and the first magnetic pole 112B" by the specific movement mode of the magnetic medium 15B" and the a state in which the second end portion 1212B" is in contact with the second magnetic pole 113B", and the first end portion 1211B" is connected to the second magnetic pole 113B" and the second end portion 1212B The switching is made between the states in which the first magnetic poles 112B are turned on, wherein the manner of movement of the magnetic medium 15B" is specific and not limited.

That is, the magnetic medium 15B" can be formed by the movement of the magnetic gap 14B" to change the magnetic flux of the coil 13B", and the specific movement of the magnetic medium 15B" in the magnetic gap 14B" In a manner, the magnetic core 12B" can be connected to the first end 1211B" and the first magnetic pole 112B" and the second end 1212B" can be connected to the second magnetic pole 113B" a state of being passed between the first end portion 1211B" and the second magnetic pole 113B" and the second end portion 1212B" is in contact with the first magnetic pole 112B" Switching is performed to increase the amount of change in the change in the magnetic flux of the coil 13B" formed by the movement of the magnetic medium 15B", but the core 12B" is at the first end portion 1211B" and a state in which the first magnetic pole 112B" is turned on and the second end portion 1212B" is in contact with the second magnetic pole 113B", and the first end portion 1211B" and the second magnetic pole 113B The switching between the states in which the phase is turned on and the second end portion 1212B" is in contact with the first magnetic pole 112B" can be The various modes of motion of the magnetic medium 15B" are implemented, and the invention is not limited thereto.

In other words, the perturbation generator 10B" of the present invention is capable of converting mechanical energy into electrical energy in response to various motion modes to avoid the mechanical energy loss caused by converting different motion modes into a specific motion mode. The power generation efficiency of the disturbance generator 10B" is increased. Further, since the disturbance generator 10B" can be adapted to convert mechanical energy into electrical energy in a plurality of motion modes, the disturbance generator 10B" of the present invention It can also be used to detect different actuation actions to generate corresponding electrical signals to obtain information of corresponding actuation actions, such as for linear motion or rotational motion, by electrical signals generated by the disturbance generator 10B". Speed measurement.

It can be understood that the first magnetic pole 112B" and the second magnetic pole 113B" are arranged to have different magnetic pole magnetic properties, that is, when the first magnetic pole 112B" is magnetic pole of the S pole, The second magnetic pole 113B" is magnetic pole magnetic of the N pole, and when the first magnetic pole 112B" is magnetic pole of the N pole, the second magnetic pole 113B" is magnetic pole of the S pole, and the present invention is This is not limited.

In detail, the first magnetic medium 151B" and the second magnetic medium 152B" are disposed in a coaxial swing motion manner, that is, in the first magnetic medium 151B" and the second magnetic medium 152B" One axis between the axes is an axis, and when the first magnetic medium 151B" is turned on at the position where the first end portion 1211B" and the first magnetic pole 112B" are turned, the axis is pivotally close to the axis When the first end portion 1211B" and the second magnetic pole 113B" are turned on, the second magnetic medium 152B" is turned on by the second end portion 1212B" and the second magnetic pole 113B" The position synchronization is rotationally rotated close to turn on the second end portion 1212B" and the first magnetic pole 112B".

Specifically, the disturbance generator 10B" further includes a link 17B", wherein the first magnetic medium 151B" and the second magnetic medium 152B" are respectively disposed at both ends of the link 17B" The first magnetic medium 151B" and the second magnetic medium 152B" can be connected by the connection of the first magnetic medium 151B" and the second magnetic medium 152B" by the connecting rod 17B" The drive is coaxially oscillated with a point on the link 17B" as a fulcrum.

It is to be noted that, in this embodiment of the invention, the first magnetic medium 151B" is disposed to be maintained in an ON state with the first end portion 1211B" to enable the magnetic gap 14B" The first magnetic pole 112B" and the second magnetic pole 113B" are alternately connected to the first end portion 1211B" in a sliding motion; the second magnetic medium 152B" is disposed to be the same as the first The two end portions 1212B" are maintained in an on state to alternately turn the first magnetic pole 112B" and the second magnetic pole 113B" to the second in a slidable motion of the magnetic gap 14B" End 1212B". Further, since the magnet assembly 11B" is disposed in an extending direction of the first end portion 1211B" and the second end portion 1212B" with the first end portion 1211B" and the second end, respectively When the portion 1212B" is close, the sliding of the magnetic medium 15B" in the magnetic gap 14B" does not collide with the magnet assembly 11B", that is, the sliding of the magnet assembly 11B" on the magnetic medium 15B" The direction is not extended. As such, when the first magnetic pole 112B" and the second magnetic pole 113B" are alternately turned on by the first magnetic medium 151B" to the first end portion 1211B", the first magnetic medium 151B "can be driven more effortlessly, likewise, the first magnetic pole 112B" and the second magnetic pole 113B" are alternately connected to the second end portion 1212B by the second magnetic medium 152B"" The second magnetic medium 152B" can also be driven more labor-savingly, that is, between the magnetic core 12B" and the magnet assembly 11B" during movement of the magnetic medium 15B". The collision occurs to cause kinetic energy loss, and thus the spoiler generator 10B" of the present invention has higher power generation efficiency and lower operating noise.

Further, the magnet assembly 11B" includes a permanent magnet 111B" and a magnetically conductive component 114B" to provide a magnetic field environment for the disturbance generator 10B" through the permanent magnet 111B", wherein the permanent magnet 111B The extending direction of the first end portion 1211B" and the second end portion 1212B" is disposed in a radial space of the magnetic core 12B", wherein the magnetic conductive component 114B" and the permanent magnet 111B Magnetically coupled to form the first magnetic pole 112B" and the second magnetic pole 113B" by the magnetic conductive component 114B", and the magnetic conductive component 114B" and the permanent magnet 111B The magnetically permeable connection causes the formation positions of the first magnetic pole 112B" and the second magnetic pole 113B" to match the specific movement mode of the magnetic medium 15B", that is, the guide The magnetic assembly 114B" is configured to be magnetically coupled to the permanent magnet 111B" to form the first end portion 1211B" and the second end portion 1212B" respectively adjacent to the first magnetic pole 112B" A positional relationship with the second magnetic pole 113B".

In detail, in this embodiment of the invention, the magnetic conductive component 114B" includes a first magnetic conductive plate 1141B" and a second magnetic conductive plate 1142B", wherein the first magnetic conductive plate 1141B" and The second magnetic conductive plates 1142B" are respectively magnetically connected to the two magnetic poles (ie, the S pole and the N pole) of the permanent magnet 111B", that is, the two magnetic poles of the permanent magnet 111B" are magnetically connected to the first One of the magnetic conductive plate 1141B" and the second magnetic conductive plate 1142B", such that the first magnetic conductive plate 1141B" forms the first magnetic pole 112B", and the second magnetic conductive plate 1142B The second magnetic pole 113B is formed. In particular, the first magnetic conductive plate 1141B" and the second magnetic conductive plate 1142B" are respectively adjacent to the first end portion 1211B" and the second portion, respectively. The end portion 1212B", that is, the permanent magnet 111B" and the first magnetic conductive plate 1141B" and the second magnetic conductive plate 1142B" respectively disposed at the two magnetic pole ends of the permanent magnet 111B" form a "" The magnet assembly 11B" of the H" shape, wherein the left and right sides of the "H" shape are the first magnetic conductive plate 1141B" and the second magnetic conductive plate 11 42B" is formed such that one of the front and rear sides of the "H" shape is adjacent to the first end portion 1211B" and the second end portion 1212B", thereby forming the first end portion 1211B And the second end portion 1212B" are simultaneously adjacent to the positional relationship of the first magnetic pole 112B" and the second magnetic pole 113B", respectively.

In comparison with the previous embodiment, those skilled in the art will further understand that the perturbation generator 10B" of the present invention passes through the magnetic medium 15B" from the magnetic core 12B" and the magnet assembly 11B". The movement of the magnetic gap 14B" is formed such that the medium within the magnetic gap 14B" changes while the magnetic field within the magnetic gap 14B" changes in response to changes in the medium within the magnetic gap 14B" And the magnetic field in the magnetic core 12B" changes in response to a change in the magnetic field in the magnetic gap 14B", so that the magnetic flux of the coil 13B" looped around the magnetic core 12B" changes Further, the coil 13B" generates electric energy, wherein the structure of the magnetic core 12B" and the magnet assembly 11B" has various embodiments according to the embodiment of the present invention, which is not limited by the present invention.

Referring to Figures 8A and 8B of the accompanying drawings of the present invention, a perturbation generator 10C in accordance with another embodiment of the present invention is illustrated, wherein Figures 8A and 8B respectively illustrate the perturbation generator 10C is a structural diagram of a different state, wherein the disturbance generator 10C includes a magnet assembly 11C, a magnetic core 12C, and two coils 13C, wherein the magnet assembly 11C includes a permanent magnet 111C for passing the The magnet 111C provides a magnetic field environment for the disturbance generator 10C, wherein the core 12C is disposed to be made of a magnetically permeable material and includes both end portions 121C, wherein the two end portions 121C of the magnetic core 12C are respectively The magnet assembly 11C is adjacent to form at least one magnetic gap 14C between the magnet assembly 11C and the two ends 121C of the magnetic core 12C, wherein the two coils 13C are looped on the magnetic The core 12C, such as when the magnetic field in the magnetic gap 14C changes in response to a change in the medium in the magnetic gap 14C, the magnetic core 12C causes two changes in response to a change in the magnetic field in the magnetic gap 14C. The magnetic flux of the coil 13C is changed to thereby the coil 13C generates electrical energy.

In detail, in this embodiment of the invention, the magnet assembly 11C has a first magnetic pole 112C and a second magnetic pole 113C, and the two ends 121C of the magnetic core 12C, that is, a first end a portion 1211C and a second end portion 1212C, wherein the first end portion 1211C is adjacent to the first pole end 112C, and the second end portion 1212C is adjacent to the second pole end 113C, The magnetic gap 14C is formed between the first end portion 1211C and the first magnetic pole end 112C adjacent thereto, the second end portion 1212C and the second magnetic pole end 113C adjacent thereto The magnetic gap 14C is formed therebetween.

Further, in this embodiment of the invention, the disturbance generator 10C further includes a magnetic medium 15C, wherein the magnetic medium 15C is disposed to be prepared using a magnetically permeable material to be The movement within the magnetic gap 14C forms a change in the medium within the magnetic gap 14C such that the magnetic field within the magnetic gap 14C changes in response to changes in the medium within the magnetic gap 14C, thereby causing the magnetic The core 12C generates electric energy to the coil 13C in response to a change in the magnetic field in the magnetic gap 14C to change the magnetic flux of the coil 13C.

It is worth mentioning that in this embodiment of the invention, the magnetic core 12C is maintained static for the magnetic medium 15C, so as to be able to maintain the coil 13C looped over the magnetic core 12C statically. The requirement for the fatigue resistance of the coil 13C is lowered, thereby enhancing the stability of the disturbance generator 10C. In addition, the coil 13C is maintained static so that there is no need to reserve the movement space of the coil 13C in the structural design of the disturbance generator 10C, which is advantageous for reducing the volume of the disturbance generator 10C. In other words, in the case where the volume of the disturbance generator 10C is maintained, the coil 13C is maintained static so that the coil 13C does not need to be reserved in the structural design of the disturbance generator 10C. The movement space is such that it is advantageous to increase the volume ratio of the coil 13C of the disturbance generator 10C, thereby improving the power generation efficiency of the disturbance generator 10C.

In addition, the magnet assembly 11C is also maintained static for the magnetic medium 15C, so that there is no need to reserve the movement space of the magnet assembly 11C in the structural design of the disturbance generator 10C, which is advantageous for reduction. The volume of the disturbance generator 10C. In other words, in the case where the volume of the disturbance generator 10C is maintained, the magnet assembly 11C is maintained static so that the structure of the disturbance generator 10C does not need to be reserved in the structural design. The movement space of the assembly 11C is such that it is advantageous to increase the volume ratio of the magnet assembly 11C of the disturbance generator 10C, thereby improving the power generation efficiency of the disturbance generator 10C.

In particular, in order to further increase the power generation efficiency of the disturbance generator 10C, in this embodiment of the invention, the magnetic medium 15C is disposed to be capable of being close to the first in the magnetic gap 14C. Switching between the position of the magnetic pole end 112C and the first end portion 1211C and the position to close the second magnetic pole 113C and the second end portion 1212C, it is understood that when the A magnetic pole 112C and the first end portion 1211C are magnetically turned on by the magnetic medium 15C, or the second magnetic pole 113C and the second end portion 1212C are magnetically turned on by the magnetic medium 15C. The magnetic core 15C, which is also provided to be made of a magnetically permeable material, has a large magnetic flux due to being magnetically connected to the first magnetic pole 112C or the second magnetic pole 113C by the magnetic medium 15C. That is, at this time, the magnetic flux in the magnetic core 15C is disconnected from the first magnetic pole 112C and the first end portion 1211C, and the second magnetic pole 113C and the second end are When the portion 1212C is also disconnected, the magnetic flux is large, so the movement of the magnetic medium 15C in the magnetic gap 14C a state in which the magnetic core 12C is in contact with the first magnetic pole 112C at the first end portion 1211C and a state in which the second end portion 1212C is in contact with the second magnetic pole 113C Switching between them can form a large amount of change in the magnetic flux of the magnetic core 12C during the switching, thereby increasing the amount of change in the magnetic flux of the coil 13C formed by the movement of the magnetic medium 15C, and further The power generation efficiency of the disturbance generator 10C is increased.

It can be understood that the magnetic medium 15C can be brought close to the magnetic gap 14C to turn on the first magnetic pole 112C and the first end portion 1211C by the specific movement mode of the magnetic medium 15C. The position is switched to be close to a position to turn on the second magnetic pole 113C and the second end portion 1212C, wherein the manner of movement of the magnetic medium 15C is specific and not limited.

That is, a change in the magnetic flux of the coil 13C that the magnetic medium 15C can move in the magnetic gap 14C, and a specific movement of the magnetic medium 15C in the magnetic gap 14C enables the The magnetic core 12C is switched between a state in which the first end portion 1211C is in contact with the first magnetic pole 112C and a state in which the second end portion 1212C is in contact with the second magnetic pole 113C. To increase the amount of change in the change in the magnetic flux of the coil 13C formed by the movement of the magnetic medium 15C, but the core 12C is at the first end portion 1211C and the first magnetic pole 112C thereof The switching between the state in which the phase is turned on and the state in which the second end portion 1212C is in contact with the second magnetic pole 113C can be realized by various movement modes of the magnetic medium 15C, and the present invention This is not limited.

As in some embodiments of the present invention, the magnetic medium 15C is disposed in a linear reciprocating manner to be remote from a position close to the first magnetic pole 112C and the first end 1211C. Turning on the positions of the second magnetic pole 113C and the second end portion 1212C; and when the position close to the second magnetic pole 113C and the second end portion 1212C is close to The position of a magnetic pole 112C and the first end 1211C.

In some embodiments of the present invention, the magnetic medium 15C is disposed in a rotational reciprocating manner to be rotationally rotated near the first magnetic pole 112C and the first end 1211C. Keeping away from the position where the second magnetic pole 113C and the second end portion 1212C are turned on; and when the position close to the second magnetic pole 113C and the second end portion 1212C is close to The position of the first magnetic pole 112C and the first end portion 1211C.

That is to say, the disturbance generator 10C of the present invention is capable of converting mechanical energy into electrical energy in response to various motion modes, thereby avoiding the mechanical energy loss caused by converting different motion modes into a specific motion mode, thereby improving the The power generation efficiency of the magnetic generator 10C is described. Further, since the disturbance generator 10C can be adapted to convert mechanical energy into electric energy in various motion modes, the disturbance generator 10C of the present invention can also be used for A corresponding electrical action is detected to generate a corresponding electrical signal to obtain information of the corresponding actuation action, such as a speed measurement for linear motion or rotational motion, by the electrical signal generated by the disturbance generator 10C.

It can be understood that the first magnetic pole 112C and the second magnetic pole 113C are set to have different magnetic pole magnetic properties, that is, when the first magnetic pole 112C is magnetic pole of the S pole, the second The magnetic pole 113C is magnetic pole magnetic on the N pole, and when the first magnetic pole 112C is magnetic pole of the N pole, the second magnetic pole 113C is magnetic pole of the S pole, which is not limited in the present invention.

In particular, in this embodiment of the invention, the first end portion 1211C and the second end portion 1212C are disposed to extend in the same direction from the magnetic core 12C, such that the first end portion can be maintained. The 1211C and the second end portion 1212C increase the length of the magnetic core 12C at a suitable distance, thereby facilitating shortening of the movement stroke of the magnetic medium 15C while increasing the number of turns of the coil 13C. It can be understood that, since the movement stroke of the magnetic medium 15C is shortened, the rate of change of the magnetic flux of the magnetic core 12C is improved under the premise that the moving speed of the magnetic medium 15C is constant, and further The number of turns of the coil 13C is increased, so that the power generation efficiency of the disturbance generator 10C is improved.

It is to be noted that, in this embodiment of the invention, the magnet assembly 11C further includes a magnetic conductive component 114C, wherein the magnetic conductive component 114C is magnetically coupled to the permanent magnet 111C to The magnetic conductive component 114C forms the first magnetic pole 112C and the second magnetic pole 113C, and is connected to the magnetic conductive of the permanent magnet 111C by the magnetic conductive component 114C, so that the first magnetic pole 112C And a position at which the second magnetic pole 113C is formed matches a specific movement mode of the magnetic medium 15C, that is, the magnetic conductive component 114C is disposed to be magnetically coupled to the permanent magnet 111C to A positional relationship in which the first end portion 1211C is close to the first magnetic pole 112C and the second end portion 1212C is close to the second magnetic pole 113C is formed.

In detail, in this embodiment of the invention, the magnetic conductive component 114C includes a first magnetic conductive plate 1141C and a second magnetic conductive plate 1142C, wherein the first magnetic conductive plate 1141C and the second conductive guide The magnetic plates 1142C are magnetically connected to the two magnetic poles (ie, the S pole and the N pole) of the permanent magnet 111C, that is, the two magnetic poles of the permanent magnet 111C are magnetically connected to the first magnetic conductive plate 1141C and the One of the second magnetic conductive plates 1142C, such that the first magnetic conductive plate 1141C forms the first magnetic pole 112C adjacent to the first end portion 1211C, and the second magnetic conductive plate 1142C The second magnetic pole 113C is formed adjacent to the second end portion 1212C. Thus, the first magnetic pole 112 and the second magnetic pole 113 have different magnetic pole magnetic properties, and the first end portion 1211C is formed close to the first magnetic pole 112C and the second end portion 1212C is formed. A positional relationship close to the second magnetic pole 113C matches a specific movement mode of the magnetic medium 15C.

That is, the magnetically conductive component 114C is in magnetic communication with the permanent magnet 111C such that the formation positions of the first magnetic pole 112C and the second magnetic pole 113C and the specific movement of the magnetic medium 15C The manners are matched, and when the positions of the two magnetic poles of the permanent magnet 111C can directly match the specific motion mode of the magnetic medium 15C, the magnetic conductive component 114C may not be set, then the first The magnetic pole end 112C and the second magnetic pole end 113C are respectively formed on two magnetic poles of the permanent magnet 111C, such as when the permanent magnet 111C is provided as a U-shaped magnet, the first end portion 1211C and the second The end portions 1212C can respectively correspond to the two magnetic poles of the U-shaped magnet and the two magnetic poles of the U-shaped magnet respectively, that is, the two magnetic poles of the U-shaped magnet are the first magnetic pole 112C and the second magnetic pole. The extreme 113C is thus matched to the particular mode of motion of the magnetic medium 15C, and the invention is not limited thereto.

It will be understood by those skilled in the art that in this embodiment of the invention, the magnetic core 12C and the magnet assembly 11C are close to each other to form the magnetic gap 14C, and the magnetic medium 15C moves in the magnetic gap 14C. When the medium in the magnetic gap 14C is changed, the magnetic field in the magnetic gap 14C changes in response to a change in the medium in the magnetic gap 14C, and the magnetic field in the magnetic core 12C is responsive to the magnetic The magnetic field in the gap 14C changes to change the magnetic flux of the coil 13C that is looped around the core 12C, thereby generating electric energy in the coil 13C, wherein the number of the magnetic medium 15C is The manner of movement does not constitute a limitation of the invention.

In order to further disclose the present invention, a modified structure of the snubber generator 10C according to this embodiment of the present invention is illustrated with reference to FIGS. 9A and 9B of the accompanying drawings of the present invention, which mainly shows A schematic structural view of the disturbance generator 10C in different states. Specifically, the disturbance generator 10C further includes a driving rod 16C, wherein the driving rod 16C has an active end 161C and a passive end 162C opposite to the active 161C end, wherein the magnetic medium 15C is Provided on the passive end 162C, wherein the drive rod 16C is configured to drive the active end 161C of the drive rod 16C to drive the passive end 162C near the first end 1211C and the first Switching between a position of a magnetic pole 112C and a position near the second end 1212C and the second magnetic pole 113C, such as when the magnetic medium 15C is disposed at the passive end 162C a medium 15C in the magnetic gap 14C between a position near the first end portion 1211C and the first magnetic pole 112C and a position near the second end portion 1212C and the second magnetic pole 113C Switching is controlled by the drive rod 16C to toggle the drive rod 16C to generate electrical energy from the coil 13C.

Referring to Figures 10A and 10B of the accompanying drawings of the present invention, a perturbation generator 10D according to another embodiment of the present invention is illustrated, wherein the perturbation generator 10D includes a magnet assembly 11D, a magnetic core 12D, and a two coil 13D, wherein the magnet assembly 11D includes a permanent magnet 111D to provide a magnetic field environment for the disturbance generator 10D through the permanent magnet 111D, wherein the magnetic core 12D is set to The magnetic material is prepared and includes both end portions 121D, wherein the two end portions 121D of the magnetic core 12D are respectively adjacent to the magnet assembly 11D, so as to be the magnet assembly 11D and the magnetic core 12D. At least one magnetic gap 14D is formed between the end portions 121D, wherein the two coils 13D are looped around the magnetic core 12D, such as when the magnetic field in the magnetic gap 14D responds to the medium in the magnetic gap 14D. When the change is changed, the magnetic core 12D causes the magnetic fluxes of the two coils 13D to be changed in response to a change in the magnetic field in the magnetic gap 14D, thereby generating electric energy in the coil 13D.

In detail, in this embodiment of the invention, the magnet assembly 11D has two first magnetic pole ends 112D and a second magnetic pole end 113D, and the two end portions 121D of the magnetic core 12D, that is, a first end a portion 1211D and a second end portion 1212D, wherein the first end portion 1211D simultaneously corresponds to one of the two first magnetic pole ends 112D and the second magnetic pole end 113D and the first magnetic pole end 112D The second magnetic poles 113D are adjacent to each other, wherein the second end portion 1212D corresponds to the second magnetic pole 113D and the other of the first magnetic poles 112D and the second magnetic pole 113D and The first magnetic poles 112D are adjacent to each other, such that the first end portion 1211D forms the magnetic gap 14D between the first magnetic pole 112D and the second magnetic pole 113D, respectively. The second end portion 1212D also forms the magnetic gap 14D between the first magnetic pole 112D and the second magnetic pole 113D, respectively, adjacent thereto.

Further, the disturbance generator 10D further includes at least one magnetic medium 15D, wherein the magnetic medium 15D is disposed to be prepared using a magnetically permeable material to move within the magnetic gap 14D by the magnetic medium 15D. Forming a change in the medium within the magnetic gap 14D such that a magnetic field within the magnetic gap 14D changes in response to a change in the medium within the magnetic gap 14D, thereby causing the magnetic core 12D to respond to the magnetic gap The change in the magnetic field within 14D changes the magnetic flux of the coil 13D to generate electrical energy at the coil 13D.

It is worth mentioning that, in this embodiment of the invention, the magnetic core 12D is maintained static for the magnetic medium 15D, so as to be able to maintain the coil 13D looped over the magnetic core 12D statically. The requirement for the fatigue resistance of the coil 13D is lowered, thereby enhancing the stability of the disturbance generator 10D. In addition, the coil 13D is maintained static so that there is no need to reserve the movement space of the coil 13D in the structural design of the disturbance generator 10D, which is advantageous for reducing the volume of the disturbance generator 10D. In other words, in the case where the volume of the disturbance generator 10D is maintained, the coil 13D is maintained static so that the coil 13D does not need to be reserved in the structural design of the disturbance generator 10D. The movement space is such that it is advantageous to increase the volume ratio of the coil 13D of the disturbance generator 10D, thereby improving the power generation efficiency of the disturbance generator 10D.

In addition, the magnet assembly 11D is also maintained static for the magnetic medium 15D, so that the structural design of the disturbance generator 10D does not need to reserve the movement space of the magnet assembly 11D, which is advantageous for reduction. The volume of the disturbance generator 10D. In other words, in the case where the volume of the disturbance generator 10D is maintained, the magnet assembly 11D is maintained static so that the structure of the disturbance generator 10D does not need to be reserved in the structure design. The movement space of the assembly 11D is such that it is advantageous to increase the volume ratio of the magnet assembly 11D of the disturbance generator 10D, thereby improving the power generation efficiency of the disturbance generator 10D.

In particular, in this embodiment of the invention, the number of the magnetic media 15D is two, that is, a first magnetic medium 151D and a second magnetic medium 152D, wherein the first magnetic medium 151D and the first The two magnetic medium 152D is disposed such that when the first magnetic medium 151D is in a position close to the first end portion 1211D and the first magnetic pole 112D close to the first end portion 1211D, The second magnetic medium 152D is synchronously located adjacent to the second end 1212D and the second magnetic pole 113D adjacent to the second end 1212D, and when the first magnetic medium 151D is located close to a position to turn on the first end portion 1211D and the second magnetic pole 113D adjacent to the first end portion 1211D, the second magnetic medium 152D is synchronously located close to The second end portion 1212D and the position of the first magnetic pole 112D adjacent to the second end portion 1212D are described.

That is, in this embodiment of the invention, the magnetic medium 15D is arranged to move the magnetic core 12D in the first end portion 1211D and the two first magnetic pole ends 112D in a specific motion manner. a state in which one phase of the first end portion 1211D is turned on and the second end portion 1212D is in contact with the second magnetic pole tip 113D, and the first end portion 1211D and the second magnetic pole end 113D The phase is turned on and the second end portion 1212D is switched between a state in which one of the two first pole ends 112D is close to the second end portion 1212D to be turned on by the magnetic medium 15D This particular mode of motion forms a reverse switching of the magnetic field within the magnetic core 12D, thereby increasing the power generation efficiency of the disruptive generator 10D.

By the specific movement mode of the magnetic medium 15D, the magnetic core 12D can be connected to the first end portion 1211D and one of the two first magnetic pole ends 112D adjacent to the first end portion 1211D. And the second end portion 1212D is in a state of being connected to the second magnetic pole 113D, and the first end portion 1211D is connected to the second magnetic pole 113D and the second end portion 1212D is A switching is made between two states of the first magnetic pole 112D adjacent to the second end portion 1212D, wherein the mode of motion of the magnetic medium 15D is specific and not limited.

That is, a change in the magnetic flux of the coil 13D that the magnetic medium 15D can move in the magnetic gap 14D, and a specific movement of the magnetic medium 15D in the magnetic gap 14D enables the The magnetic core 12D is connected to the first end portion 1211D and one of the two first magnetic pole ends 112D adjacent to the first end portion 1211D, and the second end portion 1212D and the second magnetic pole end 113D a state in which the first end portion 1211D is connected to the second magnetic pole 113D and the second end portion 1212D and the two first magnetic pole ends 112D are adjacent to the second end portion Switching between one of the phase-on states of the 1212D to form a reverse switching of the magnetic field in the magnetic core 12D by the specific movement of the magnetic medium 15D, thereby improving the magnetic medium 15D The amount of change in the change in the magnetic flux of the coil 13D formed by the movement, but the magnetic core 12D is adjacent to the first end portion 1211D of the first end portion 1211D and the two first magnetic pole ends 112D. a state in which the phase is turned on and the second end portion 1212D is connected to the second magnetic pole 113D, The first end portion 1211D is connected to the second magnetic pole 113D and the second end portion 1212D is connected to one of the two first magnetic pole ends 112D adjacent to the second end portion 1212D. The switching between states can be achieved by various modes of movement of the magnetic medium 15D, which is not limited by the present invention.

In other words, the perturbation generator 10D of the present invention is capable of converting mechanical energy into electrical energy in response to various motion modes, thereby avoiding the mechanical energy loss caused by converting different motion modes into a specific motion mode, thereby improving The power generation efficiency of the disturbance generator 10D, further, the disturbance generator 10D of the present invention can also be used because the disturbance generator 10D can be adapted to convert mechanical energy into electrical energy in a variety of motion modes. Corresponding electrical signals are generated to detect different actuation actions to obtain information of corresponding actuation actions, such as speed measurement for linear motion or rotational motion, by electrical signals generated by the disturbance generator 10D.

It can be understood that the first magnetic pole 112D and the second magnetic pole 113D are arranged to have different magnetic pole magnetic properties, that is, when the first magnetic pole 112D is magnetic pole of the S pole, the second The magnetic pole 113D is magnetic pole magnetic on the N pole, and when the first magnetic pole 112D is magnetic pole of the N pole, the second magnetic pole 113D is magnetic pole of the S pole, which is not limited in the present invention.

In particular, in this embodiment of the invention, the first end portion 1211D and the second end portion 1212D are disposed to extend in the same direction to the magnetic core 12D such that the first end portion can be maintained. The 1211D and the second end portion 1212D increase the length of the magnetic core 12D at a suitable distance, thereby facilitating shortening of the movement stroke of the magnetic medium 15D while increasing the number of turns of the coil 13D. It can be understood that, since the movement stroke of the magnetic medium 15D is shortened, the rate of change of the magnetic flux of the magnetic core 12D is improved under the premise that the moving speed of the magnetic medium 15D is constant, and further The number of turns of the coil 13D is increased, so that the power generation efficiency of the disturbance generator 10D is improved.

Further, in this embodiment of the invention, the second magnetic pole 113D and the two first magnetic poles 112D are disposed in the same plane to facilitate the first magnetic medium 151D and the second The magnetic medium 152D slides within the magnetic gap 14D, thereby reducing the motion loss of the magnetic medium 15D, thereby increasing the conversion rate of the disturbance generator 10D to convert mechanical kinetic energy into electrical energy.

Further, in this embodiment of the invention, the magnet assembly 11D is further provided with a filler 115D between the first magnetic pole 112D and the second magnetic pole 113D, wherein the filler 115D is set Is a non-magnetic material, and forms a complete with the second magnetic pole 113D and the two first magnetic poles 112D in a plane in which the second magnetic pole 113D and the two magnetic poles 112D are located. The plane, thereby further facilitating the sliding of the magnetic medium 15D in the complete plane, thereby increasing the conversion rate of the disruptive generator 10D to convert mechanical kinetic energy into electrical energy.

Further, in this embodiment of the invention, the first magnetic medium 151D and the second magnetic medium 152D are disposed in a coaxial co-directional reciprocating manner to when the first magnetic medium 151D is connected Positioning the first end portion 1211D and the first magnetic pole 112D adjacent to the first magnetic medium 151 movably close to turn on the first end portion 1211D and the second magnetic pole end At 113D, the second magnetic medium 152D is in the same direction as the first magnetic medium 151D and is synchronously close to the position of the second end portion 1212D and the second magnetic pole 113D. Turning on the second end portion 1212D and the first magnetic pole end 112D adjacent to the second end portion 1212D; and when the first magnetic medium 151D is turned on, the first end portion 1211D and the The second magnetic medium 152D when the position of the second magnetic pole 113D is movably close to turn on the first end portion 1211D and the first magnetic pole 112D adjacent to the first end portion 1211D Turning on the second end portion 1212D and the position of the first magnetic pole 112D adjacent to the second end portion 1212D First motion coaxial with the magnet 151D close to the same medium to switch on the second end portion and said second pole 1212D 113D and the synchronization.

In detail, in this embodiment of the invention, the disturbance generator 10D further includes a link 17D, wherein the first magnetic medium 151D and the second magnetic medium 152D are respectively disposed on the link Both ends of the 17D are connected to the first magnetic medium 151D and the second magnetic medium 152D by the link 17D, so that the first magnetic medium 151D and the second magnetic medium 152D can be Drive ground synchronous motion.

It is worth mentioning that, in some embodiments of the present invention, the first magnetic medium 151D and the second magnetic medium 152D can also be arranged in a rotating manner, with reference to FIG. 10A of the drawings of the present invention. As shown, in the state of the disturbance generator 10D shown in FIG. 10A, when the first magnetic medium 151D and the second magnetic medium 152D are disposed with the center line AA of the magnetic core 12D When the intersection of the connecting rod 17D is a circular motion of the center, the first magnetic medium 151D and the second magnetic medium 152D can communicate with the first magnetic medium 151D in a circular motion with the center of the first magnetic medium 151D. a portion 1211D and the first magnetic pole 112D, and the second magnetic medium communicates with the second end portion 1212D and the second magnetic pole 113D, and the first magnetic medium 151D communicates with the second The end portion 1212D and the first magnetic pole 112D are switched between a state in which the second magnetic medium 152D communicates with the first end portion 1211D and the second magnetic pole 113D.

Further referring to FIG. 10A of the drawings of the present invention, in the state of the disturbance generator 10D shown in FIG. 10A, when the first magnetic medium 151D and the second magnetic medium 152D are set to When the center line AA of the magnetic core 12D is in a circular motion at the intersection of the connecting rods 17D, the first magnetic medium 151D and the second magnetic medium 152D can be circularly moved in the center of the core The first magnetic medium 151D communicates with the first end portion 1211D and the second magnetic pole 113D, and the second magnetic medium 152D communicates with the second end portion 1212D and the first magnetic pole 112D, and The first magnetic medium 151D communicates with the second end portion 1212D and the second magnetic pole 113D, and the second magnetic medium 152D communicates with the first end portion 1211D and the first magnetic pole 112D Switch between.

Thus, those skilled in the art should further understand that the number and structure of the magnetic medium 15D are not limited, that is, the first magnetic medium 151D and the second magnetic medium 152D are both the magnetic medium 15D, both The switching between the state of the disturbance generator 10D shown in FIG. 10A and the state shown in FIG. 10B can be realized by various movement modes of the magnetic medium 15D. The invention is not limited thereto.

It is to be noted that, in this embodiment of the invention, the magnet assembly 11D further includes a magnetic conductive component 114D, wherein the magnetic conductive component 114D is magnetically coupled to the permanent magnet 111D to The magnetic conductive component 114D forms the first magnetic pole 112D and the second magnetic pole 113D, and is connected to the magnetic conductive of the permanent magnet 111D by the magnetic conductive component 114D, so that the first magnetic pole 112D And a position at which the second magnetic pole 113D is formed matches a specific movement mode of the magnetic medium 15D, that is, the magnetic conductive component 114D is disposed to be magnetically coupled to the permanent magnet 111D to Forming the first end portion 1211D while corresponding to one of the two first magnetic poles 112D and the second magnetic pole 113D to be close to the first magnetic pole 112D and the second magnetic pole 113D, And the second end portion 1212D simultaneously corresponds to the position where the second magnetic pole 113D and the other first magnetic pole 112D are close to the second magnetic pole 113D and the first magnetic pole 112D. relationship.

In detail, in this embodiment of the invention, the magnetic conductive component 114D includes a first magnetic conductive plate 1141D and a second magnetic conductive plate 1142D, wherein the first magnetic conductive plate 1141D and the second conductive guide The magnetic plates 1142D are magnetically connected to the two magnetic poles (ie, the S pole and the N pole) of the permanent magnet 111D, that is, the two magnetic poles of the permanent magnet 111D are magnetically connected to the first magnetic conductive plate 1141D and the One of the second magnetic conductive plates 1142D, such that the first magnetic conductive plates 1141D form two first magnetic pole ends 112D respectively adjacent to the first end portion 1211D and the second end portion 1212D, And forming, on the second magnetic conductive plate 1142D, the second magnetic pole 113D which is adjacent to the first end portion 1211D and the second end portion 1212D. Thus, the first magnetic pole 112 and the second magnetic pole 113 have different magnetic pole magnetic properties, and the first end portion 1211D is formed to simultaneously correspond to one of the two first magnetic poles 112D and the second The magnetic pole end 113D is adjacent to the first magnetic pole end 112D and the second magnetic pole end 113D, and the second end portion 1212D simultaneously corresponds to the second magnetic pole end 113D and the other of the first magnetic poles The positional relationship of the extreme 112D to the second magnetic pole 113D and the first magnetic pole 112D is such that it matches the specific motion of the magnetic medium 15D.

Further referring to FIG. 11 of the accompanying drawings of the present invention, the perturbation generator 10D according to a further modified embodiment of the previous embodiment of the present invention is illustrated, wherein the disturbance magnetic generation The machine further includes a reset element 18D, wherein the reset element 18D is configured to maintain an initial state of the first magnetic medium 151D and the second magnetic medium 152D, wherein in the initial state, the first The magnetic medium 151D is maintained at a position where the first end portion 1211D and the first magnetic pole 112D are turned on, and the second magnetic medium 152D is maintained to be turned on to the second end portion 1212D and the second The position of the magnetic pole 113D is such that when the first magnetic medium 151D is externally driven to a position close to the first end portion 1211D and the second magnetic pole 113D, and the second magnetic medium 152D is driven synchronously The reset element 18D is capable of resetting the first magnetic medium 151D and the second magnetic medium 152D to the state after the external force is released, to a position close to the second end portion 1212D and the first magnetic pole 112D Initial state.

It is worth mentioning that in this embodiment of the invention, the reset element 18D is provided as a spring 181D, wherein the spring 181D is disposed at the first magnetic medium 151D and the second magnetic medium 152D in the initial state, when the first magnetic medium 151D is externally driven to a position close to the first end portion 1211D and the second magnetic pole 113D, and the second magnetic medium 152D is synchronously driven The spring 181D is compressed to a position close to the second end portion 1212D and the first magnetic pole 112D, such that after the external force is released, the spring 181D turns the first magnetic medium 151D and The second magnetic medium 152D returns to the initial state.

Referring further to FIG. 12 of the accompanying drawings of the present invention, the perturbation generator 10D according to a further modified embodiment of the previous embodiment of the present invention is illustrated, wherein the perturbation power generation The machine further includes a drive rod 16D, wherein the drive rod 16D has an active end 161D and a passive end 162D opposite the active end 161D, wherein the drive rod 16D is configured to toggle the drive rod 16D The active end 161D drives the passive end 162D to swing between the first end 1211D and the second end 1212D, wherein the link 17D is pivotally disposed on the drive rod The passive end 162D of the 16D drives the synchronous movement of the first magnetic medium 151D and the second magnetic medium 152D by the toggle of the drive end 161D of the drive lever 16D.

It will be understood by those skilled in the art that in this embodiment of the invention, the magnetic core 12D and the magnet assembly 11D are close to each other to form the magnetic gap 14D, and the magnetic medium 15D moves in the magnetic gap 14D. When the medium in the magnetic gap 14D is changed, the magnetic field in the magnetic gap 14D changes in response to a change in the medium in the magnetic gap 14D, and the magnetic field in the magnetic core 12D is responsive to the magnetic The magnetic field in the gap 14D changes to change the magnetic flux of the coil 13D that is looped over the magnetic core 12D, thereby generating electrical energy in the coil 13D, wherein the number of the magnetic medium 15D is The manner of movement, as well as the number of said coils 13D, does not constitute a limitation of the invention.

Referring to Figures 13A and 13B of the accompanying drawings of the present invention, a perturbation generator 10E according to another embodiment of the present invention is illustrated, wherein the perturbation generator 10E includes a magnet assembly 11E, a magnetic core 12E, and two coils 13E, wherein the magnet assembly 11E includes a permanent magnet 111E to provide a magnetic field environment for the disturbance generator 10E through the permanent magnet 111E, wherein the magnetic core 12E is set to The magnetic material is prepared and includes both end portions 121E, wherein the two end portions 121E of the magnetic core 12E are respectively adjacent to the magnet assembly 11E, so as to be the magnet assembly 11E and the magnetic core 12E. At least one magnetic gap 14E is formed between the end portions 121E, wherein the two coils 13E are looped around the magnetic core 12E, such as when the magnetic field in the magnetic gap 14E responds to the medium in the magnetic gap 14E. When the change is changed, the magnetic core 12E changes the magnetic flux of the two coils 13E in response to a change in the magnetic field in the magnetic gap 14E, thereby generating electric energy in the coil 13E.

In detail, in this embodiment of the invention, the two end portions 121E of the magnetic core 12E, that is, a first end portion 1211E and a second end portion 1212E, wherein the first end portion 1211E and the The second end portion 1212E is disposed to extend in the same direction to the magnetic core 12E, so as to increase the magnetic core while maintaining the first end portion 1211E and the second end portion 1212E at a suitable distance. The length of 12E is such that it is advantageous to shorten the length of the space occupied by the magnetic core 12E while increasing the number of turns of the coil 13E. It can be understood that since the number of turns of the coil 13E is increased, the power generation efficiency of the disturbance generator 10E is improved.

In detail, in this embodiment of the invention, the magnet assembly 11E has a first magnetic pole 112E and a second magnetic pole 113E, wherein the first end portion 1211E simultaneously corresponds to the first magnetic pole 112E And the second magnetic pole 113E are adjacent to the first magnetic pole 112E and the second magnetic pole 113E, and the second end 1212E simultaneously corresponds to the first magnetic pole 112E and the second The magnetic pole 113E is close to the first magnetic pole 112E and the second magnetic pole 113E. Specifically, the magnet assembly 11E is disposed between the first end portion 1211E and the second end portion 1212E, such that the first end portion 1211E and the first magnetic pole end 112E and the The magnetic gap 14E is formed between the second magnetic poles 113E, and the second end portion 1212E also forms the magnetic gap 14E with the first magnetic pole 112E and the second magnetic pole 113E, respectively.

Further, the disturbance generator 10E further includes at least one magnetic medium 15E, wherein the magnetic medium 15E is disposed to be prepared with a magnetically permeable material to be relative to the magnetic medium 14E by the magnetic medium 15E. The movement of the magnetic gap 14E forms a change in the medium within the magnetic gap 14E such that the magnetic field within the magnetic gap 14E changes in response to changes in the medium within the magnetic gap 14E, thereby causing the magnetic core 12E Electrical energy is generated in the coil 13E by changing the magnetic flux of the coil 13E in response to a change in the magnetic field within the magnetic gap 14E.

It is to be noted that, in this embodiment of the invention, the magnetic medium 15E is disposed integrally formed on the end portion 121E of the magnetic core 12E, so as to be described by the magnet assembly 11 Movement between the first end portion 1211E and the second end portion 1212E forms a movement of the magnetic medium 15E relative to the magnetic gap 14E of the magnetic gap 15E, thereby forming a medium in the magnetic gap 14E The change.

In particular, in this embodiment of the invention, the magnetic core 12E is maintained static for the magnet assembly 11E such that the coil 13E that is looped over the magnetic core 12E is statically lowered. The requirement of the fatigue resistance of the coil 13E further enhances the stability of the disturbance generator 10E. In addition, the coil 13E is maintained static so that there is no need to reserve the movement space of the coil 13E in the structural design of the disturbance generator 10E, which is advantageous for reducing the volume of the disturbance generator 10E. In other words, in the case where the volume of the disturbance generator 10E is maintained, the coil 13E is maintained static so that the coil 13E does not need to be reserved in the structural design of the disturbance generator 10E. The movement space is such that it is advantageous to increase the volume ratio of the coil 13E of the disturbance generator 10E, thereby improving the power generation efficiency of the disturbance generator 10E.

Further, in this embodiment of the invention, the number of the magnetic media 15E is three, that is, a first magnetic medium 151E and two second magnetic media 152E, wherein the first magnetic medium 151E is set to Extending from the first end portion 1211E toward the magnetic gap 14E and integrally forming the magnetic core 12E, wherein the two second magnetic media 152E are respectively disposed from the second end portion 1212E The magnetic gap 14E extends to be integrally formed with the magnetic core 12E as a whole.

In particular, the magnetic medium 15E and the magnet assembly 11E are further disposed such that when the first magnetic pole 112E is in proximity to the first magnetic medium 151E such that the first magnetic pole 112E and the first When the one end portion 1211E is in the position where the first magnetic medium 151E is turned on, the second magnetic pole 113E is in proximity to one of the two second magnetic media 152E to make the second magnetic pole 113E and a position at which the second end portion 1212E is turned on by the second magnetic medium 152E; and when the second magnetic pole 113E is in proximity to the first magnetic medium 151E such that the second magnetic pole 113E and When the first end portion 1211E is in a position where the first magnetic medium 151E is turned on, the first magnetic pole 112E is in proximity to the other of the two second magnetic media 152E to make the first magnetic portion The extreme 112E and the second end 1212E are in a position where the second magnetic medium 152E is turned on.

That is, in this embodiment of the invention, the magnetic core 12E and the magnetic medium 15E are maintained static, and the magnet assembly 11E is disposed at the first end portion 1211E and the second end The movement between the portions 1212E connects the magnetic core 12E to the first end portion 1211E and the first magnetic pole 112E, and the second end portion 1212E is opposite to the second magnetic pole 113E a state of being turned on, switching between a state in which the first end portion 1211E is in contact with the second magnetic pole 113E, and a state in which the second end portion 1212E is in contact with the first magnetic pole 112E Thus, the reverse switching of the magnetic field in the magnetic core 12E is formed by the movement of the magnet assembly 11E between the first end portion 1211E and the second end portion 1212E, thereby improving the magnetic disturbance. The power generation efficiency of the generator 10E.

It can be understood that the first magnetic pole 112E and the second magnetic pole 113E are arranged to have different magnetic pole magnetic properties, that is, when the first magnetic pole 112E is magnetic pole of the S pole, the second The magnetic pole 113E is magnetic pole magnetic on the N pole, and when the first magnetic pole 112E is magnetic pole of the N pole, the second magnetic pole 113E is magnetic pole of the S pole, which is not limited in the present invention.

Further, in this embodiment of the invention, the magnet assembly 11E is disposed in a reciprocating manner between the first end portion 1211E and the second end portion 1212E along the first magnetic field The wiring direction of the extreme 112E and the second magnetic pole 113E reciprocates such that when the first magnetic pole 112E is in proximity to the first magnetic medium 151E such that the first magnetic pole 112E and the first When the end portion 1211E is in the position where the first magnetic medium 151E is turned on, the second magnetic pole 113E is in proximity to one of the two second magnetic media 152E to make the second magnetic pole 113E and the a position at which the second end portion 1212E is turned on by the second magnetic medium 152E; and when the second magnetic pole 113E is in proximity to the first magnetic medium 151E such that the second magnetic pole 113E and the When the first end portion 1211E is turned on by the first magnetic medium 151E, the first magnetic pole 112E is in proximity to the other of the two second magnetic media 152 to make the first magnetic pole 112E and the second end 1212E are connected by the second magnetic medium 152E .

It is to be noted that, in this embodiment of the invention, the magnet assembly 11E further includes a magnetic conductive component 114E, wherein the magnetic conductive component 114E is magnetically coupled to the permanent magnet 111E to The magnetic conductive component 114E forms the first magnetic pole 112E and the second magnetic pole 113E, and is connected to the magnetic conductive of the permanent magnet 111E by the magnetic conductive component 114E, so that the first magnetic pole 112E The position at which the second magnetic pole 113E is formed matches the position of the magnetic medium 15E. That is, the magnetically permeable component 114E is configured to be magnetically coupled to the permanent magnet 111E to form the first end 1211E while corresponding to the first magnetic pole 112E and the second magnetic pole 113E is adjacent to the first magnetic pole 112E and the second magnetic pole 113E, and the second end 1212E simultaneously corresponds to the first magnetic pole 112E and the second magnetic pole 113E A positional relationship in which the first magnetic pole 112E and the second magnetic pole 113E are close to each other is described.

In detail, in this embodiment of the invention, the magnetic conductive component 114E includes a first magnetic conductive plate 1141E and a second magnetic conductive plate 1142E, wherein the first magnetic conductive plate 1141E and the second conductive guide The magnetic plates 1142E are magnetically connected to the two magnetic poles (ie, the S pole and the N pole) of the permanent magnet 111E, that is, the two magnetic poles of the permanent magnet 111E are magnetically connected to the first magnetic conductive plate 1141E and the One of the second magnetic conductive plates 1142E, such that the first magnetic conductive plate 1141E forms the first magnetic pole 112E at the same time as the first end portion 1211E and the second end portion 1212E, and Forming, on the second magnetic conductive plate 1142E, the second magnetic pole 113E simultaneously adjacent to the first end portion 1211E and the second end portion 1212E, such that the first magnetic pole 112 and the The second magnetic pole 113 has a different magnetic pole magnetic property.

Specifically, the first magnetic conductive plate 1141E and the second magnetic conductive plate 1142E are respectively adjacent to the first end portion 1211E and the second end portion 1212E, that is, the permanent magnets 111E and are respectively set. The first magnetic conductive plate 1141E and the second magnetic conductive plate 1142E at the two magnetic pole ends of the permanent magnet 111E form an "H"-shaped magnet assembly 11E, wherein the "H" shape is left and right The two sides are formed by the first magnetic conductive plate 1141E and the second magnetic conductive plate 1142E, so that the upper and lower ends of the "H" shape are respectively associated with the first end portion 1211E and the second portion The end portions 1212E are adjacent to each other to form a positional relationship in which the first end portion 1211E and the second end portion 1212E are simultaneously adjacent to the first magnetic pole tip 112E and the second magnetic pole end 113E, respectively.

So that the magnetic core 12E is connected to the first magnetic pole 112E at the first end portion 1211E by swinging left and right by the magnet assembly 11E disposed in the "H" shape, and a state in which the second end portion 1212E is in contact with the second magnetic pole 113E, and the first end portion 1211E is connected to the second magnetic pole 113E, and the second end portion 1212E is The state in which the first magnetic pole 112E is turned on is switched.

Further, in this embodiment of the invention, the disruptive generator further includes a reset element 18E, wherein the reset element 18E is configured to maintain an initial state of the magnet assembly 11E, wherein In the initial state of the magnet assembly 11E, the magnet assembly 11E is maintained such that the first magnetic pole 112E thereof is connected to the first end portion 1211E by the first magnetic medium 151E, and the The second magnetic pole 113E is in a state in which one of the two second magnetic media 152E is turned on at the second end portion 1212E. Thus, when the magnet assembly 11E is externally driven to the second magnetic pole 113E thereof, the first magnetic medium 151E is connected to the first end portion 1211E, and the first magnetic pole 112E thereof is When the other of the second magnetic medium 152E is turned on in the state of the second end portion 1212E, the resetting member 18E can reset the magnet assembly 11E to the initial state after the external force is released.

Referring to Figures 14A, 14B, 15A and 15B of the accompanying drawings of the present invention, a perturbation generator 10F according to a variant embodiment of the above-described embodiment of the present invention is illustrated, wherein the disturbance is illustrated The magneto generator 10F includes a magnet assembly 11F, a magnetic core 12F, and a coil 13F, wherein the magnet assembly 11F includes a permanent magnet 111F, wherein the magnet assembly 11F includes a permanent magnet 111F to pass the permanent magnet 111F provides a magnetic field environment for the disturbance generator 10F, wherein the magnetic core 12F is disposed to be made of a magnetically permeable material and includes both end portions 121F, wherein the two end portions 121F of the magnetic core 12F are respectively The magnet assembly 11F is adjacent to each other to form at least one magnetic gap 14F between the magnet assembly 11F and the two end portions 121F of the magnetic core 12F, wherein the two coils 13F are looped around the magnetic core 12F, such as when the magnetic field in the magnetic gap 14F changes in response to the change of the magnetic gap 14F, the magnetic core 12F causes the two coils 13F to respond to changes in the magnetic field in the magnetic gap 14F. The magnetic flux is changed to generate electricity in the coil 13F .

In detail, in this embodiment of the invention, the two end portions 121F of the magnetic core 12F, that is, a first end portion 1211F and a second end portion 1212F, wherein the first end portion 1211F and the The second end portion 1212F is disposed to extend in the same direction to the magnetic core 12F, so as to increase the magnetic core while maintaining the first end portion 1211F and the second end portion 1212F at a suitable distance. The length of 12F is such that it is advantageous to shorten the length of the space occupied by the magnetic core 12F while increasing the number of turns of the coil 13F. It can be understood that since the number of turns of the coil 13F is increased, the power generation efficiency of the disturbance generator 10F is improved.

Further, the magnet assembly 11F has a first magnetic pole 112F and a second magnetic pole 113F, wherein the first end portion 1211F simultaneously corresponds to the first magnetic pole 112F and the second magnetic pole 113F Adjacent to the first magnetic pole 112F and the second magnetic pole 113F, the second end portion 1212F simultaneously corresponds to the first magnetic pole 112F and the second magnetic pole 113F and the first The magnetic pole end 112F and the second magnetic pole end 113F are close to each other. Specifically, the magnet assembly 11F is disposed between the first end portion 1211F and the second end portion 1212F, such that the first end portion 1211F and the first magnetic pole end 112F and the The magnetic gap 14F is formed between the second magnetic poles 113F, and the second end portion 1212F also forms the magnetic gap 14F with the first magnetic pole 112F and the second magnetic pole 113F, respectively.

In particular, in this embodiment of the invention, the magnetic core 12F is maintained static for the magnet assembly 11F such that the coil 13F that is looped over the magnetic core 12F is statically lowered. The requirement of the fatigue resistance of the coil 13F further enhances the stability of the disturbance generator 10F. In addition, the coil 13F is maintained static so that there is no need to reserve the movement space of the coil 13F in the structural design of the disturbance generator 10F, which is advantageous for reducing the volume of the disturbance generator 10F. In other words, in the case where the volume of the disturbance generator 10F is maintained, the coil 13F is maintained static so that the coil 13F does not need to be reserved in the structural design of the disturbance generator 10F. The movement space is such that it is advantageous to increase the volume ratio of the coil 13F of the disturbance generator 10F, thereby improving the power generation efficiency of the disturbance generator 10F.

Further, in this embodiment of the invention, the magnetic core 12F is maintained static, and the magnet assembly 11F is disposed to move between the first end portion 1211F and the second end portion 1212F, Forming a change of the magnetic gap 14F between the first end portion 1211F and the first magnetic pole 112F and the second magnetic pole 113F, respectively, and the second end portion 1212F is respectively associated with the first a change in the magnetic gap 14F between the magnetic pole 112F and the second magnetic pole 113F such that a magnetic field within the magnetic gap 14F changes in response to a change in the magnetic gap 14F, thereby causing the magnetic core The 12F changes the magnetic flux of the two coils 13F in response to a change in the magnetic field in the magnetic gap 14F, thereby generating electric energy in the coil 13F.

In particular, the magnet assembly 11F is disposed to move between the first end portion 1211F and the second end portion 1212F to the magnetic core 12F at the first end portion 1211F and the first portion a magnetic pole end 112F is turned on, and the second end portion 1212F is in contact with the second magnetic pole 113F, and the first end portion 1211F is connected to the second magnetic pole 113F. And switching between the state in which the second end portion 1212F is in contact with the first magnetic pole 112F, such that the magnet assembly 11F is at the first end portion 1211F and the second end portion The motion between 1212F forms a reverse switching of the magnetic field within the magnetic core 12F, thereby increasing the power generation efficiency of the disturbance generator 10F.

It can be understood that the first magnetic pole 112F and the second magnetic pole 113F are arranged to have different magnetic pole magnetic properties, that is, when the first magnetic pole 112F is magnetic pole of the S pole, the second The magnetic pole 113F exhibits magnetic pole magneticism of the N pole, and when the first magnetic pole 112F is magnetic pole of the N pole, the second magnetic pole 113F exhibits magnetic pole magneticity of the S pole, which is not limited in the present invention.

Further, in this embodiment of the invention, the magnet assembly 11F is disposed in a pivotal movement between the first end 1211F and the second end 1212F, with the first A point between the magnetic pole end 112F and the second magnetic pole end 113F is pivotally reciprocally pivoted to be close to the first end portion 1211F and the first end portion 1211F when the first magnetic pole 112F is adjacent to the first end portion 1211F When the position is turned on, the second magnetic pole 113F is in a position close to the second end portion 1212F and connected to the second end portion 1212F; and when the second magnetic pole 113F is at When the first end portion 1211F is close to the first end portion 1211F, the first magnetic pole 112F is adjacent to the second end portion 1212F and is opposite to the second end portion 1212F. The position to be connected. Thus, the reverse switching of the magnetic field in the magnetic core 12F is formed by the reciprocal rotation of the magnet assembly 11F between the first end portion 1211F and the second end portion 1212F, thereby improving the magnetic disturbance. The power generation efficiency of the generator 10F.

It is to be noted that the magnet assembly 11F further includes a magnetic conductive component 114F, wherein the magnetic conductive component 114F is magnetically coupled to the permanent magnet 111F, so that the magnetic conductive component 114F forms the first The magnetic pole end 112F and the second magnetic pole end 113F are connected to the magnetic conductive body of the permanent magnet 111F by the magnetic conductive component 114F, so that the first magnetic pole 112F and the second magnetic pole 113F The formation position matches the movement of the magnet assembly 11F. That is, the magnetic conductive component 114F is configured to be magnetically coupled to the permanent magnet 111F to form the first end portion 1211F while corresponding to the first magnetic pole 112F and the second magnetic pole end. 113F is adjacent to the first magnetic pole 112F and the second magnetic pole 113F, and the second end 1212F simultaneously corresponds to the first magnetic pole 112F and the second magnetic pole 113F A positional relationship in which the first magnetic pole 112F and the second magnetic pole 113F are close to each other is described.

Specifically, the magnetic conductive component 114F includes a first magnetic conductive plate 1141F and a second magnetic conductive plate 1142F, wherein the first magnetic conductive plate 1141F and the second magnetic conductive plate 1142F and the permanent magnet respectively The two magnetic poles (ie, the S pole and the N pole) of the 111F are magnetically connected, that is, the two magnetic poles of the permanent magnet 111F are magnetically coupled to one of the first magnetic conductive plate 1141F and the second magnetic conductive plate 1142F. So that the first magnetic conductive plate 1141F forms the first magnetic pole 112F simultaneously adjacent to the first end portion 1211F and the second end portion 1212F, and the second magnetic conductive plate 1142F Forming the second magnetic pole 113F simultaneously adjacent to the first end portion 1211F and the second end portion 1212F, such that the first magnetic pole end 112 and the second magnetic pole end 113 have different magnetic poles magnetic.

Specifically, the first magnetic conductive plate 1141F and the second magnetic conductive plate 1142F are respectively adjacent to the first end portion 1211F and the second end portion 1212F, that is, the permanent magnets 111F and are respectively set. The first magnetic conductive plate 1141F and the second magnetic conductive plate 1142F of the two magnetic pole ends of the permanent magnet 111F form an "H"-shaped magnetic conductive component 114F, wherein the "H" shape The left and right sides are formed by the first magnetic conductive plate 1141F and the second magnetic conductive plate 1142F, so that the upper and lower ends of the "H" shape are respectively associated with the first end portion 1211F and the first The two end portions 1212F are adjacent to each other, thereby forming a positional relationship in which the first end portion 1211F and the second end portion 1212F are respectively close to the first magnetic pole tip 112F and the second magnetic pole end 113F.

It can be understood that the magnet assembly 11F disposed in the "H" shape is between the first end portion 1211F and the second end portion 1212F with the center of the "H" shape as a fulcrum. a pivoting movement, that is, the magnetic core 12F is connected to the first magnetic pole 112F at the first end portion 1211F, and the second end portion 1212F is opposite to the second magnetic pole 113F a state of being turned on, switching between a state in which the first end portion 1211F is in contact with the second magnetic pole 113F, and a state in which the second end portion 1212F is in contact with the first magnetic pole 112F Thereby, a reverse switching of the magnetic field in the magnetic core 12F is formed, thereby increasing the power generation efficiency of the disturbance generator 10F.

Specifically, in this embodiment of the invention, the disturbance generator 10F further includes a mount 19F, wherein the magnet assembly 11F is between the first end 1211F and the second end 1212F a pivoting shaft is pivotally fixed to the mounting seat 19F at a center of the "H" shape to pivot the magnetic core 12F to the first by the pivotal movement of the magnet assembly 11F a state in which the end portion 1211F is connected to the first magnetic pole 112F, and the second end portion 1212F is in contact with the second magnetic pole 113F, and the first end portion 1211F and the second end The magnetic pole 113F is turned on, and the state in which the second end portion 1212F is in contact with the first magnetic pole 112F is switched.

It is to be noted that, in this embodiment of the invention, the disturbance generator 10F further includes a driving elastic piece 20F, wherein the driving elastic piece 20F is disposed on the magnet assembly 11F to The oscillating drive of the drive spring 20F drives the reciprocating pivotal movement of the magnet assembly 11F.

It can be understood that the driving elastic piece 20F extends to the magnet assembly 11F such that the stroke of the driving elastic piece 20F swinging is enlarged with respect to the rotation of the magnet assembly 11F, that is, the magnet assembly 11F The pivotal movement between the first end 1211F and the second end 1212F can be set to have a smaller motion stroke to facilitate reducing the movement of the magnet assembly 11F to spatially reduce the The volume of the magnetic generator 10F is disturbed, and the pivoting stroke of the magnet assembly 11F is amplified by the driving elastic piece 20F to obtain a suitable swinging motion of the driving elastic piece 20F, thereby facilitating the enhancement of the magnetic stirrer 10F. Operational sense.

In addition, it is worth mentioning that the driving elastic piece 20F is arranged to be prepared with an elastic material so as to be capable of being forced to store a certain elastic potential energy and to drive the magnet assembly 11F when the stored elastic potential energy reaches a certain critical value. Pivoting the core 12F to the first pole end 112F at the first end 1211F, and the second end 1212F is connected to the second pole end 113F The state is switched between a state in which the first end portion 1211F is connected to the second magnetic pole 113F and a state in which the second end portion 1212F is in contact with the first magnetic pole 112F. So as to enhance the state in which the magnetic core 12F is connected to the first magnetic pole 112F at the first end portion 1211F, and the second end portion 1212F is in contact with the second magnetic pole 113F, The stability of the switching between the state in which the first end portion 1211F is in contact with the second magnetic pole 113F and the second end portion 1212F is in contact with the first magnetic pole 112F.

In other words, the driving elastic piece 20F completes the magnetic core 12F at the first end only when the elastic potential energy stored therein reaches a certain critical value to drive the pivotal movement of the magnet assembly 11F. a state in which 1211F is connected to the first magnetic pole 112F, and the second end portion 1212F is in contact with the second magnetic pole 113F, and the first end portion 1211F and the second magnetic pole end The switching between the state in which the 113F phase is turned on and the second end portion 1212F is in contact with the first magnetic pole 112F is such that the magnetic flux of the coil 13F is improved by shortening the completion time of the switching operation. The rate of change enhances the power generation efficiency of the disturbance generator 10F and makes the completion time of the switching action tend to be the same each time to contribute to enhancing the stability of the power generation efficiency of the disturbance generator 10F.

In particular, in this embodiment of the invention, the disturbance generator 10F further includes a reset element 18F, wherein the reset element 18F is configured to maintain an initial state of the magnet assembly 11F, wherein In the initial state of the magnet assembly 11F, the magnet assembly 11F is maintained such that its first magnetic pole 112F is turned on at the first end portion 1211F, and the second magnetic pole 113F thereof is The state of being connected to the second end portion 1212F. Thus, when the magnet assembly 11F is externally driven to the second magnetic pole 113F thereof, the first end portion 1211F is turned on, and the first magnetic pole 112F thereof is turned on at the second end. In the state of the portion 1212F, the reset element 18F can reset the magnet assembly 11F to the initial state after the external force is released.

Specifically, in this embodiment of the invention, the reset member 18F is provided as a torsion spring 182F, wherein the torsion spring 182F is coupled between the mount 19F and the drive dome 20F to In the initial state of the magnet assembly 11F, when the magnet assembly 11F is externally driven to the second magnetic pole 113F thereof, the first end portion 1211F is turned on, and the first magnetic pole thereof When the 112F is turned on in the state of the second end portion 1212F, the torsion spring 182F is compressed to store a certain elastic potential energy, so that the torsion spring 182F will move the magnet assembly after the external force is released. 11F returns to the initial state.

It will be understood by those skilled in the art that in this embodiment of the invention, the perturbation generator 10F causes the magnetic gap 14F to change by the movement of the magnet assembly 11F relative to the magnetic core 12F. The magnetic field in the magnetic gap 14F changes in response to the change of the magnetic gap 14F, and the magnetic field in the magnetic core 12F changes in response to a change in the magnetic field in the magnetic gap 14F, thereby causing the ring to be trapped. The magnetic flux of the coil 13F of the magnetic core 12F is changed to generate electric energy for the coil 13F, wherein the structure of the magnetic core 12F and the magnet assembly 11F has various kinds according to this embodiment of the present invention. The present invention is not limited thereto.

In order to further describe the present invention, as shown in FIG. 16 of the accompanying drawings of the present invention, and with reference to FIGS. 1 to 15B of the drawings of the present invention, the present invention also provides a power generation method, wherein the power generation method includes the following steps :

(a) being adjacent to a magnetic core 12G and a magnet assembly 11G to form at least one magnetic gap 14G between the magnetic core 12G and the magnet assembly 11G;

(b) driving the movement of a magnetic medium 15G within the magnetic gap 14G relative to the magnetic gap 14G to form a change in the magnetic field within the magnetic gap 14G such that the magnetic flux of the magnetic core 12G is responsive to The change in the magnetic field in the magnetic gap 14G changes, and electric energy is generated in at least one coil 13G surrounded by the magnetic core 12G.

In particular, in step (b), the magnetic core 12G is maintained static, and in some embodiments of the invention, the magnet assembly 11G is also maintained static, such that by enabling the same space The space of the coil 13G and the magnet assembly 11G increases the power generation efficiency of the power generation method.

Those skilled in the art can understand that the above embodiments are merely examples, and the features of the different embodiments may be combined with each other to obtain an embodiment which is easily conceived according to the disclosure of the present invention but is not explicitly indicated in the drawings.

Those skilled in the art should understand that the embodiments of the present invention described in the above description and the accompanying drawings are only by way of example and not limitation. The object of the invention has been achieved completely and efficiently. The present invention has been shown and described with respect to the embodiments of the present invention, and the embodiments of the present invention may be modified or modified without departing from the principles.

Claims

A disturbance generator, characterized in that it comprises:

a magnet assembly, wherein the magnet assembly includes at least one permanent magnet to provide a magnetic field environment for the disturbance generator by the permanent magnet;

a magnetic core, wherein the magnetic core is configured to be fabricated using a magnetically permeable material, wherein the magnetic core includes both ends, wherein at least one of the ends of the magnetic core is adjacent to the magnet assembly to Forming at least one magnetic gap between the magnet assembly and the end portion adjacent thereto;

At least one coil, wherein the coil is looped over the magnetic core, wherein the magnetic core is responsive to the magnetic gap when a magnetic field within the magnetic gap changes in response to a change in the magnetic gap The change in the magnetic field causes the magnetic flux of the core to be altered to generate electrical energy at the coil.
A magnetic disrupting generator according to claim 1 wherein said magnetically disturbing generator further comprises at least one magnetic medium, wherein said magnetic medium is arranged to be prepared from a magnetically permeable material for said magnetic medium Movement within the magnetic gap forms a change in the medium within the magnetic gap.
A magnetic disrupting generator according to claim 2, wherein said magnetic core is maintained static to increase the volume fraction of said coil to said disturbing generator, thereby increasing power generation of said disturbing generator effectiveness.
The magnetic stir generator according to claim 3, wherein said magnet assembly is maintained static to increase a volume ratio of said permanent magnet to said disturbing generator, thereby increasing said magnetic stirrer Power generation efficiency.
A magnetic transformer according to claim 4, wherein said magnet assembly has a first magnetic pole and a second magnetic pole, wherein said first pole end and said second pole end extend in the same direction a magnet assembly, wherein one of the two ends of the magnetic core is simultaneously adjacent to the first magnetic pole and the second magnetic pole to be between the end and the first magnetic pole And forming the magnetic gap between the end portion and the second magnetic pole, respectively.
The magnetic stir generator according to claim 5, wherein said magnetic medium is disposed to be capable of being close to said magnetic end of said first magnetic pole and said end portion adjacent said magnet assembly a position between the position close to the second magnetic pole and the end to be turned on by the magnetic medium to turn on the first magnetic pole and the end a position, and switching between switching on the position of the second pole end and the end portion forms an inverse change in the magnetic line of inductance within the core, thereby increasing the amount of change in the magnetic flux of the core And further improving the power generation efficiency of the disturbance generator.
A magnetic disrupting generator according to claim 6 wherein said magnet assembly further comprises a magnetically permeable component, wherein said magnetically permeable component is magnetically coupled to said permanent magnet, said magnetically permeable component forming said first a magnetic pole end and the second magnetic pole, and the first magnetic pole and the second magnetic pole extend from the magnet assembly in the same direction by the magnetic conductive connection of the magnetic conductive component and the permanent magnet The ground is close to the positional relationship of one of the two ends.
The magnetic transformer according to claim 7, wherein said magnetic conductive component comprises a first magnetic conductive plate and a second magnetic conductive plate, wherein said first magnetic conductive plate and said second magnetic conductive plate respectively Connecting the two magnetic poles of the permanent magnet to the first magnetic pole to form the first magnetic pole, and the second magnetic pole to form the second magnetic pole, so that The first magnetic pole and the second magnetic pole have different magnetic pole magnetic properties.
A magnetic disrupting generator according to claim 4, wherein said magnet assembly has two first magnetic poles and two second magnetic poles, said two ends of said magnetic core, i.e., a first end and a first a two end portion, wherein the first end portion is adjacent to one of the two first magnetic poles and one of the two second magnetic poles, respectively, the second end portion and the other of the second end portions respectively One magnetic pole is adjacent to the other of the second pole ends.
The magnetic transformer according to claim 9, wherein said magnetic medium has two, that is, a first magnetic medium and a second magnetic medium, wherein said first magnetic medium and said second magnetic medium are Providing that when the first magnetic medium is in a position to close the first end and the first magnetic pole close to the first end, the second magnetic medium is turned on a second end portion and a position of the second magnetic pole adjacent to the second end portion, and when the first magnetic medium is in contact with the first end portion and opposite to the first end portion The second magnetic medium is in a position to close the second end and the first magnetic pole adjacent to the second end when approaching the position of the second magnetic pole.
A magnetic disrupting generator according to claim 10, wherein said first end and said second end are arranged to extend away from both ends of said magnetic core.
The magnetic stir generator according to claim 10, wherein said first end portion and said second end portion are disposed to extend in the same direction from said magnetic core to set said magnet assembly to said magnetic core The length of the spoiler generator is shortened laterally.
The magnetic disrupting generator of claim 12 wherein said magnet assembly is disposed between said first end and said second end.
A magnetic disrupting generator according to claim 4, wherein said magnet assembly has a first magnetic pole and a second magnetic pole, wherein said two ends of said magnetic core are a first end and a first a second end, wherein the first end is adjacent to the first pole end and the second pole end simultaneously between the first end and the first pole end, and The magnetic gap is formed between the first end portion and the second magnetic pole end, wherein the second end portion is adjacent to the first magnetic pole end and the second magnetic pole end simultaneously to the second The magnetic gap is formed between the end and the first magnetic pole, and between the second end and the second magnetic pole.
The magnetic disrupting generator of claim 14 wherein said first end and said second end are each disposed to extend in the same direction from said core.
A magnetic stir generator according to claim 15, wherein said magnet assembly is disposed between said first end and said second end simultaneously with said first end and said second end The departments are close together.
The magnetic stir generator according to claim 16, wherein said magnetic medium has two, that is, a first magnetic medium and a second magnetic medium, wherein said first magnetic medium and said second magnetic medium are Providing that when the first magnetic medium is in a position to turn on the first end and the first magnetic pole, the second magnetic medium is in the second end and the second magnetic An extreme position, and when the first magnetic medium is in a position to close the first end and the second magnetic pole, the second magnetic medium is in the second end and the The position of the first magnetic pole.
A magnetic transformer according to claim 17, wherein said magnet assembly further comprises a magnetically conductive component, wherein said magnetically conductive component is magnetically coupled to said permanent magnet, said magnetically conductive component forming said first a magnetic pole end and the second magnetic pole, and the first magnetic pole and the second magnetic pole are formed at the first end by the magnetically conductive component and the magnetic conductive connection of the permanent magnet The second end portions are respectively adjacent to the positional relationship of the first end portion and the second end portion.
The magnetic transformer according to claim 18, wherein said magnetic conductive component comprises a first magnetic conductive plate and a second magnetic conductive plate, wherein said first magnetic conductive plate and said second magnetic conductive plate respectively The two magnetic poles of the permanent magnet are magnetically coupled to form the first magnetic pole to form the first magnetic pole, and the second magnetic pole to form the second magnetic pole.
The magnetic stir generator according to claim 19, wherein said permanent magnet and said first magnetic conductive plate and said second magnetic conductive plate respectively disposed at two magnetic pole ends of said permanent magnet form an "H The magnet assembly of the shape, wherein the left and right sides of the "H" shape are formed by the first magnetic conductive plate and the second magnetic conductive plate, wherein the upper and lower ends of the "H" shape Adjacent to the first end portion and the second end portion, respectively, to form the first end portion and the second end portion simultaneously adjacent to the first magnetic pole end and the second magnetic pole end, respectively The positional relationship.
A magnetic disrupting generator according to claim 20, wherein said magnetic disrupting generator further comprises a link, wherein said first magnetic medium and said second magnetic medium are respectively disposed at both ends of said connecting rod The connection of the first magnetic medium and the second magnetic medium by the connecting rod, so that the first magnetic medium and the second magnetic medium can be driven on the connecting rod One point is coaxially oscillating.
The magnetic stir generator according to claim 15, wherein the magnet assembly is disposed to simultaneously extend with the first end and the second end with the first end and the second The ends are close together.
The magnetic stir generator according to claim 22, wherein said magnetic medium has two, that is, a first magnetic medium and a second magnetic medium, wherein said first magnetic medium and said second magnetic medium are Providing that when the first magnetic medium is in a position to turn on the first end and the first magnetic pole, the second magnetic medium is in the second end and the second magnetic An extreme position, and when the first magnetic medium is in a position to close the first end and the second magnetic pole, the second magnetic medium is in the second end and the The position of the first magnetic pole.
A magnetic stir generator according to claim 23, wherein said magnet assembly further comprises a magnetically conductive component, wherein said magnetically conductive component is magnetically coupled to said permanent magnet, said magnetically conductive component forming said first a magnetic pole end and the second magnetic pole, and the first magnetic pole and the second magnetic pole are formed at the first end by the magnetically conductive component and the magnetic conductive connection of the permanent magnet The extending direction of the second end portion is simultaneously close to the positional relationship of the first end portion and the second end portion, respectively.
The magnetic transformer according to claim 24, wherein said magnetic conductive component comprises a first magnetic conductive plate and a second magnetic conductive plate, wherein said first magnetic conductive plate and said second magnetic conductive plate respectively The two magnetic poles of the permanent magnet are magnetically coupled to form the first magnetic pole to form the first magnetic pole, and the second magnetic pole to form the second magnetic pole.
The magnetic stir generator according to claim 25, wherein said permanent magnet and said first magnetic conductive plate and said second magnetic conductive plate respectively disposed at two magnetic pole ends of said permanent magnet form an "H The magnet assembly of the shape, wherein the left and right sides of the "H" shape are formed by the first magnetic conductive plate and the second magnetic conductive plate, wherein the front and rear sides of the "H" shape are One side is adjacent to the first end and the second end to form the first end while being adjacent to the first pole end and the second pole end, and the second The end portion is also close to the positional relationship of the first magnetic pole and the second magnetic pole.
A magnetic disrupting generator according to claim 26, wherein said magnetic disrupting generator further comprises a link, wherein said first magnetic medium and said second magnetic medium are respectively disposed at both ends of said connecting rod The connection of the first magnetic medium and the second magnetic medium by the connecting rod, so that the first magnetic medium and the second magnetic medium can be driven on the connecting rod One point is coaxially oscillating.
A magnetic disrupting generator according to claim 4, wherein said two ends of said magnetic core are a first end and a second end, wherein said first end and said second end The magnetic core is extended in the same direction to increase the length of the magnetic core to increase the number of turns of the coil, thereby improving the power generation efficiency of the disturbance generator.
A magnetic transformer according to claim 28, wherein said magnet assembly has a first magnetic pole and a second magnetic pole, wherein said first pole end and said second pole end extend in the same direction a magnet assembly, wherein the first end portion is adjacent to the first magnetic pole end corresponding to the first magnetic pole end, and the second end portion corresponds to the second magnetic pole end and the second magnetic portion Extremely close together, such that the magnetic gap is formed between the first end and the first magnetic pole, respectively, between the second end and the second magnetic pole.
A magnetic stir generator according to claim 29, wherein said magnetic medium is disposed to be close to a position to close said first end and said first magnetic pole and to approach said second Switching between the end and the position of the second pole end such that the magnetic medium is adjacent to the first end and the first pole end and adjacent to the second end and A change in the magnitude of the magnetic flux of the magnetic core is formed during switching between the positions of the second magnetic poles, thereby generating electrical energy in the coil.
A magnetic disrupting generator according to claim 30, wherein said magnetic disrupting generator further comprises a drive rod, wherein said drive rod has an active end and a passive end opposite said active end, wherein said a drive rod is provided to toggle the active end to drive the passive end at a position near the first end and the first pole end and near the second end and the second pole end Switching between positions, wherein the magnetic medium is disposed at the passive end, such that the magnetic medium is within the magnetic gap at a position close to the first end and the first magnetic pole and close to Switching between the position of the second end and the second pole end is controlled by the drive rod to enable the drive rod to generate electrical energy at the coil.
A magnetic disrupting generator according to claim 28, wherein said magnet assembly has two first magnetic poles and a second magnetic pole between said first magnetic poles, wherein said first ends simultaneously correspond One of the first magnetic poles and the second magnetic pole are adjacent to the first magnetic pole and the second magnetic pole, wherein the second end corresponds to the second The magnetic pole and the other first magnetic pole are adjacent to the second magnetic pole and the first magnetic pole, such that the first end is respectively adjacent to the first magnetic body Forming the magnetic gap between the extreme and the second magnetic pole, the second end also forming the magnetic gap between the first magnetic pole and the second magnetic pole respectively adjacent thereto .
A magnetic disrupting generator according to claim 32, wherein said magnetic medium has two, i.e., a first magnetic medium and a second magnetic medium, wherein said first magnetic medium and said second magnetic medium are Providing that when the first magnetic medium is in a position to close the first end and the first magnetic pole close to the first end, the second magnetic medium is turned on a position of the second end portion and the second magnetic pole, and when the first magnetic medium is in a position to close the first end portion and the second magnetic pole end, the second magnetic medium is in contact Passing the second end portion and the position of the first magnetic pole adjacent to the second end portion to synchronize the magnetic gap by the first magnetic medium and the second magnetic medium The reciprocating motion forms an inverse change in the magnetic flux of the magnetic core, thereby increasing the power generation efficiency of the spoiler generator.
A snubber generator according to claim 33, wherein said snubber generator further comprises a link, wherein said first magnetic medium and said second magnetic medium are respectively disposed at both ends of said link And connecting the first magnetic medium and the second magnetic medium by the connecting rod to the first magnetic medium and the second magnetic medium, so that the first magnetic medium and the second magnetic medium can be driven to move synchronously with each other.
A magnetic disrupting generator according to claim 34, wherein said magnetic disrupting generator further comprises a reset element, wherein said reset element is arranged to maintain an initial of said first magnetic medium and said second magnetic medium a state, wherein in the initial state, the first magnetic medium is maintained at a position where the first end and the first magnetic pole close to the first end are turned on, and a second magnetic medium is maintained at a position where the second end and the second magnetic pole are turned on, such that when the first magnetic medium is driven by an external force to be turned on, the first end and the The position of the second magnetic pole, and the second magnetic medium is synchronously driven to the position of the second end and the first magnetic pole close to the second end, the reset The component is capable of resetting the first magnetic medium and the second magnetic medium to the initial state after the external force is released.
A snubber generator according to claim 35, wherein said snubber generator further comprises a drive rod, wherein said drive rod has an active end and a passive end opposite said active end, wherein said a drive rod is provided to toggle the active end of the drive rod to drive the passive end to swing between the first end and the second end, wherein the link is pivotally And being disposed at the passive end of the driving rod to drive synchronous movement of the first magnetic medium and the second magnetic medium by a toggle of the driving end of the driving rod.
A magnetic disrupting generator according to claim 32, wherein said magnetic medium has two, i.e., a first magnetic medium and a second magnetic medium, wherein said first magnetic medium and said second magnetic medium are Providing that when the first magnetic medium is in a position to close the first end and the first magnetic pole close to the first end, the second magnetic medium is turned on a position of the second end and the second pole end, and when the first magnetic medium is in a position to close the second end and the first pole end adjacent to the second end And the second magnetic medium is in a position to turn on the first end and the second magnetic pole to be concentric with the magnetic gap by the first magnetic medium and the second magnetic medium Rotation generates an inverse change in the magnetic line of inductance of the magnetic core, thereby increasing the power generation efficiency of the spoiler generator.
A magnetic stir generator according to any one of claims 32 to 37, wherein said second magnetic pole and said first magnetic poles are disposed in the same plane such that said magnetic medium is capable of said magnetic The movement loss of the magnetic medium is slidably reduced in the gap, thereby increasing the conversion rate of the disturbance generator to convert mechanical kinetic energy into electrical energy.
A magnetic disrupting generator according to claim 38, wherein a filler is further disposed between said first magnetic pole and said second magnetic pole, wherein said filler is disposed to be a non-magnetic material to Forming a complete plane with the second pole end and the two first pole ends in a plane in which the second pole end and the two pole ends are located, thereby reducing the magnetic medium The complete planar sliding resistance, which in turn increases the conversion rate of the oscillating generator to convert mechanical kinetic energy into electrical energy.
A magnetic disrupting generator according to claim 3, wherein said two ends of said magnetic core are a first end and a second end, wherein said first end and said second end The magnetic core is extended in the same direction to increase the length of the magnetic core to increase the number of turns of the coil, thereby improving the power generation efficiency of the disturbance generator.
A magnetic transformer according to claim 40, wherein said magnet assembly has a first magnetic pole and a second magnetic pole, wherein said first end corresponds to said first magnetic pole and said first Two magnetic poles are closely adjacent to the first magnetic pole end and the second magnetic pole end, the second end portion simultaneously corresponding to the first magnetic pole end and the second magnetic pole end and the first magnetic pole An extreme portion is adjacent to the second magnetic pole so that the first end portion can form the magnetic gap between the first magnetic pole end and the second magnetic pole end, respectively, and the second end portion is also The magnetic gap can be formed between the first magnetic pole and the second magnetic pole, respectively.
A magnetic disrupting generator according to claim 26, wherein said magnetic medium is disposed integrally formed at said end of said magnetic core such that said magnet assembly is at said first end and said The movement between the second ends forms a movement of the magnetic medium relative to the magnetic gap of the magnetic gap, thereby forming a change in the medium within the magnetic gap.
A magnetic disrupting generator according to claim 42, wherein said magnetic medium is three in number, i.e., a first magnetic medium and two second magnetic medium, wherein said first magnetic medium is disposed from said The first end portion extends toward the magnetic gap and is integrally formed integrally with the magnetic core, wherein the two second magnetic media are respectively disposed to extend from the second end portion to the magnetic gap The magnetic core is integrally formed as a whole.
A magnetic disrupting generator according to claim 43 wherein said magnet assembly is further arranged to be in proximity to said first magnetic medium such that said first magnetic pole is opposite said first end When the portion is turned on by the first magnetic medium, the second magnetic pole is adjacent to one of the two second magnetic media such that the second magnetic pole and the second end are a position at which the second magnetic medium is turned on, and when the second magnetic pole is in proximity to the first magnetic medium such that the second magnetic pole and the first end are subjected to the first magnetic When the medium is turned on, the first magnetic pole is adjacent to the other of the two second magnetic media such that the first magnetic pole and the second end are the second magnetic medium The position that is turned on.
A magnetic stir generator as claimed in claim 44, wherein said magnetic disrupting generator further comprises a reset element, wherein said reset element is arranged to maintain an initial state of said magnet assembly, wherein said magnet In the initial state of the assembly, the magnet assembly is maintained at a level at which the first magnetic pole is connected to the first end by the first magnetic medium, and the second magnetic pole thereof is a state in which one of the second magnetic media is connected to the second end portion, such that when the magnet assembly is externally driven to the second magnetic pole thereof, the first magnetic medium is turned on a first end portion, and wherein the first magnetic pole is in a state in which the other of the two second magnetic media is connected to the second end portion, the resetting member is capable of resetting the external force after the external force is released The magnet assembly is in the initial state.
A magnetic disrupting generator according to claim 45, wherein said magnet assembly further comprises a magnetically permeable component, wherein said magnetically permeable component is magnetically coupled to said permanent magnet, said magnetically permeable component forming said first a magnetic pole end and the second magnetic pole, and the first magnetic pole and the second magnetic pole are formed at the first end by the magnetically conductive component and the magnetic conductive connection of the permanent magnet The second end portions are respectively adjacent to the positional relationship of the first end portion and the second end portion.
A magnetic stir generator according to claim 46, wherein said magnetic conductive assembly comprises a first magnetic conductive plate and a second magnetic conductive plate, wherein said first magnetic conductive plate and said second magnetic conductive plate respectively The two magnetic poles of the permanent magnet are magnetically coupled to form the first magnetic pole to form the first magnetic pole, and the second magnetic pole to form the second magnetic pole.
The magnetic stir generator according to claim 47, wherein said permanent magnet and said first magnetic conductive plate and said second magnetic conductive plate respectively disposed at two magnetic pole ends of said permanent magnet form an "H The magnet assembly of the shape, wherein the left and right sides of the "H" shape are formed by the first magnetic conductive plate and the second magnetic conductive plate, wherein the upper and lower ends of the "H" shape Adjacent to the first end and the second end, respectively, to form the first end while being adjacent to the first pole end and the second pole end, and the second end It is also close to the positional relationship of the first magnetic pole and the second magnetic pole.
A magnetic transformer according to claim 1, wherein said magnetic core is maintained static to increase a volume ratio of said coil to said disturbance generator, thereby increasing power generation of said disturbance generator effectiveness.
A magnetic disrupting generator according to claim 49, wherein said two ends of said magnetic core are a first end and a second end, wherein said first end and said second end The magnetic core is extended in the same direction to increase the length of the magnetic core to increase the number of turns of the coil, thereby improving the power generation efficiency of the disturbance generator.
A magnetic stir generator according to claim 50, wherein said magnet assembly is disposed between said first end and said second end simultaneously with said first end and said second end The departments are close together.
A magnetic disrupting generator according to claim 51, wherein said magnet assembly has a first magnetic pole and a second magnetic pole, wherein said first end simultaneously corresponds to said first magnetic pole and said Two magnetic poles are closely adjacent to the first magnetic pole end and the second magnetic pole end, the second end portion simultaneously corresponding to the first magnetic pole end and the second magnetic pole end and the first magnetic pole An extreme portion is adjacent to the second magnetic pole so that the first end portion can form the magnetic gap between the first magnetic pole end and the second magnetic pole end, respectively, and the second end portion is also The magnetic gap can be formed between the first magnetic pole and the second magnetic pole, respectively.
A magnetic disrupting generator according to claim 52, wherein said magnet assembly is further arranged to be turned on when said first magnetic pole is connected to said first end a second end, and when the first magnetic pole is connected to the second end, the second magnetic pole is connected to the first end.
A magnetic disrupting generator according to claim 53, wherein said magnet assembly is further configured to be pivotally movable about a point between said first magnetic pole and said second magnetic pole, When the first magnetic pole is in a position that is connected to the first end, the second magnetic pole is in a position that is in contact with the second end, and when the second When the magnetic pole is in a position that is in contact with the first end, the first magnetic pole is in a position that is in contact with the second end.
A magnetic disrupting generator according to claim 54 wherein said magnet assembly further comprises a magnetically permeable component, wherein said magnetically permeable component is magnetically coupled to said permanent magnet, said magnetically permeable component forming said first a magnetic pole end and the second magnetic pole, and the first magnetic pole and the second magnetic pole are formed at the first end by the magnetically conductive component and the magnetic conductive connection of the permanent magnet The second end portions are respectively adjacent to the positional relationship of the first end portion and the second end portion.
A magnetic stir generator according to claim 55, wherein said magnetic conductive assembly comprises a first magnetic conductive plate and a second magnetic conductive plate, wherein said first magnetic conductive plate and said second magnetic conductive plate respectively The two magnetic poles of the permanent magnet are magnetically coupled to form the first magnetic pole to form the first magnetic pole, and the second magnetic pole to form the second magnetic pole.
A magnetic flux generator according to claim 56, wherein said permanent magnet and said first magnetic conductive plate and said second magnetic conductive plate respectively disposed at two magnetic pole ends of said permanent magnet form an "H The magnet assembly of the shape, wherein the left and right sides of the "H" shape are formed by the first magnetic conductive plate and the second magnetic conductive plate, wherein the upper and lower ends of the "H" shape Adjacent to the first end and the second end, respectively, to form the first end while being adjacent to the first pole end and the second pole end, and the second end It is also close to the positional relationship of the first magnetic pole and the second magnetic pole.
A magnetic disrupting generator according to claim 57, wherein said magnet assembly is arranged to be pivotally movable about a center of said "H" shape.
A magnetic disrupting generator according to claim 58, wherein said magnetic disrupting generator further comprises a mount, wherein said magnet assembly is disposed between said first end and said second end, A pivot axis is pivotally secured to the mount with the center of the "H" shape.
A snubber generator according to claim 59, wherein said snubber generator further comprises a drive shrapnel, wherein said drive shrapnel is disposed on said magnet assembly for driving by oscillating said drive shrapnel, A reciprocating pivotal motion of the magnet assembly is driven.
A magnetic stir generator according to claim 60, wherein said drive shrapnel is arranged to be made of an elastic material.
A magnetic stir generator according to claim 61, wherein said magnetic disrupting generator further comprises a reset element, wherein said reset element is arranged to maintain an initial state of said magnet assembly, wherein said magnet In the initial state of the assembly, the magnet assembly is maintained such that its first magnetic pole is turned on at the first end, and the second magnetic pole is turned on at the second end status.
A power generation method, characterized in that the power generation method comprises the following steps:

(a) bringing at least one end of a core of the loop having at least one coil adjacent to a magnet assembly to form at least one magnetic gap between the end and the magnet assembly;

(b) driving a magnetic medium in the magnetic gap relative to the movement of the magnetic gap to form a change in a magnetic field in the magnetic gap, thereby causing a magnetic field in the magnetic gap by the magnetic core The magnetic flux of the magnetic core is varied in response to generate electrical energy from the coil.
The power generation method according to claim 63, wherein said magnet assembly is maintained static according to step (b) to form a change in a magnetic field in said magnetic gap by movement of said magnetic medium in said magnetic gap .
The power generation method according to claim 64, wherein according to the step (b), the movement of the magnetic medium in the magnetic gap is set to an inverse change capable of forming a magnetic line of the magnetic core to improve The power generation efficiency of the magnetic generator is described.