阅读说明：本技术 人体动能收集装置及其转换方法 (Human body kinetic energy collecting device and conversion method thereof ) 是由 廖维新 蔡明京 汪家华 于 2019-02-01 设计创作，主要内容包括：提供了一种用于嵌入可穿戴式电子设备的人体动能收集装置。该装置可包括底座；设置为圆环状并与底座连接的第一转子,该第一转子可相对于底座周向旋转,其中,在第一转子的表面可设置多对第一永磁体；与第一转子同轴心地固定在第一转子上的重锤；设置为圆环状并与第一转子同轴心地连接至底座的第二转子,该第二转子可相对于底座周向旋转,其中,在第二转子的表面可设置多对第二永磁体；在第一转子与第二转子之间与第一转子同轴心地固定至底座的调制环；以及在第二转子的与第一转子相对的一侧与第一转子同轴心地固定至底座的定子,其中在该定子上布置有线圈。(A human body kinetic energy collecting apparatus for embedding a wearable electronic device is provided. The apparatus may include a base; the first rotor is arranged in a ring shape and connected with the base, and can rotate circumferentially relative to the base, wherein a plurality of pairs of first permanent magnets can be arranged on the surface of the first rotor; a weight fixed coaxially with the first rotor; a second rotor provided in a ring shape and concentrically connected to the base with the first rotor, the second rotor being circumferentially rotatable with respect to the base, wherein a plurality of pairs of second permanent magnets may be provided on a surface of the second rotor; a modulation ring fixed to the base coaxially with the first rotor between the first rotor and the second rotor; and a stator fixed to the base concentrically with the first rotor on a side of the second rotor opposite to the first rotor, wherein a coil is arranged on the stator.)

1. A human kinetic energy collection device for embedding a wearable electronic device, wherein the human kinetic energy collection device comprises:

a base;

the first rotor is arranged in a circular ring shape and connected with the base, the first rotor can rotate circumferentially relative to the base, and a plurality of pairs of first permanent magnets are arranged on the surface of the first rotor;

a weight fixed coaxially with the first rotor;

a second rotor provided in a ring shape and connected to the base coaxially with the first rotor, the second rotor being circumferentially rotatable with respect to the base, wherein a plurality of pairs of second permanent magnets are provided on a surface of the second rotor;

a modulation loop; a second rotor secured to the base coaxially with the first rotor between the first rotor and the second rotor; and

a stator fixed to the base coaxially with the first rotor on a side of the second rotor opposite to the first rotor, wherein a coil is arranged on the stator.

2. The human body kinetic energy collecting device of claim 1,

the heavy hammer is a ring with a central angle less than 180 degrees.

3. The human body kinetic energy collecting device of claim 2,

the modulation ring comprises a plurality of magnetic conduction blocks, and the magnetic conduction blocks are arranged in a ring shape along the same circumference.

4. The human body kinetic energy collecting device of claim 3, wherein,

the plurality of magnetic conduction blocks are integrally formed by adopting a numerical control machining method, a wire cutting method, a powder metallurgy method or a 3D printing method.

5. The human body kinetic energy collecting device of claim 4, wherein,

the first rotor is a low speed rotor and the second rotor is a high speed rotor.

6. The human body kinetic energy collecting device of claim 4, wherein,

the plurality of magnetic conductive blocks are manufactured in blocks and filled with a hard material to enhance mechanical strength.

7. The human body kinetic energy collecting device of claim 4, wherein,

the central axes of the magnetic conduction blocks are obliquely arranged relative to the axis of the base so as to reduce the cogging moment.

8. The human body kinetic energy collecting device of claim 5, wherein,

the weight, the first rotor, the modulation ring, the second rotor, and the stator are concentrically arranged in the axial direction.

9. The human body kinetic energy collecting device of claim 5, wherein,

the weight, the first rotor, the modulation ring, the second rotor, and the stator are concentrically arranged in a radial direction.

10. The human body kinetic energy collecting device of claim 8,

the first rotor is provided with a first guide groove which is coaxial with the first rotor, the second rotor is provided with a second guide groove which is coaxial with the second rotor,

the base is provided with a first matching guide groove matched with the first guide groove and a second matching guide groove matched with the second guide groove,

the first rotor comprises a first sliding piece which is arranged in a first space defined by the first guide groove and the first guide groove in a matched mode so that the first rotor can rotate circumferentially relative to the stator;

the second rotor includes a second slider disposed in a second space defined by the second guide groove and the second guide groove in cooperation so that the second rotor is circumferentially rotated with respect to the stator.

11. The human body kinetic energy collecting device of claim 9,

the first rotor is provided with a first guide groove coaxial with the first rotor, the second rotor is provided with a second guide groove coaxial with the second rotor, and the first guide groove and the second guide groove are arranged in the first rotor,

the human body kinetic energy collecting device further comprises:

a first stationary ring fixed on the base and provided with a first fitting guide groove that fits the first guide groove, the first rotor being circumferentially rotatable relative to the base via the first stationary ring; and

a second stationary ring fixed on the base and provided with a second fitting guide groove that fits with the second guide groove, the second rotor being circumferentially rotatable relative to the base via the second stationary ring.

12. The human body kinetic energy collecting device of claim 11,

the first rotor comprises a first sliding piece which is arranged in a first space defined by the first guide groove and the first guide groove in a matched mode, so that the first rotor rotates circumferentially relative to the stator; and

the second rotor includes a second slider disposed in a second space defined by the second guide groove and the second guide groove in cooperation so that the second rotor is circumferentially rotated with respect to the stator.

13. The human body kinetic energy collecting device of claim 10 or 12, wherein,

the first slider and the second slider are balls, an

The first slider and the second slider are made of a low friction material.

14. The human body kinetic energy collecting device of claim 4, wherein,

the second permanent magnets are arranged in a single row of permanent magnets, and the number of pairs of the single row of permanent magnets is smaller than that of the first permanent magnets.

15. The human body kinetic energy collecting device of claim 4, wherein,

the second permanent magnets are arranged as double-row permanent magnets, a magnetic field shielding ring is arranged between a first row of the double-row permanent magnets and a second row of the double-row permanent magnets, and

the first row of permanent magnets is mated with the second rotor and the number of pairs of the first row of permanent magnets is less than the number of pairs of the first permanent magnets.

16. The human body kinetic energy collecting device of claim 15, wherein,

the first row of permanent magnets is arranged to be magnetized in a radial direction, and the second row of permanent magnets is arranged to be magnetized in an axial direction.

17. The human body kinetic energy collecting device of claim 15, wherein,

the first row of permanent magnets and the second row of permanent magnets are arranged to be magnetized in a radial direction.

18. The human body kinetic energy collecting device of claim 1,

the stator is provided with a tooth slot, and the coil is wound in the tooth slot.

19. The human body kinetic energy collecting device of claim 1,

the coil is disposed on the stator by a printed circuit.

20. A human body kinetic energy conversion method for a wearable electronic device comprises the following steps:

acquiring a first kinetic energy exerted on the electronic device;

generating a low-frequency magnetic field by using the kinetic energy;

high-frequency modulating the low-frequency magnetic field to generate a high-frequency magnetic field;

acquiring a second kinetic energy by using the high-frequency magnetic field; and

and generating an induced current by using the second kinetic energy.

21. A wearable electronic device comprising the human body kinetic energy collecting apparatus as claimed in claim 8 or 9.

Technical Field

The present application relates to a human body kinetic energy collecting device, and more particularly, to a human body kinetic energy collecting device that can be embedded in a wearable electronic apparatus. In addition, the application also relates to a human body kinetic energy conversion method capable of being used for the embedded wearable electronic equipment.

Background

With the increasing development of science and technology, various portable and wearable intelligent electronic devices such as mobile phones, smart watches, smart bracelets, virtual reality glasses and wearable health monitoring devices play an increasingly important role in life and work of people. Currently, these devices rely primarily on battery power. However, due to the limitation of the prior art, the capacity of the battery is limited, and the power required by the electronic device is larger and larger, and the requirement of the size of the electronic device is more and more strict, so that the battery life is shorter and shorter. Meanwhile, the existing method for generating power by using the inertia wheel generally has large thickness and volume and is difficult to be embedded into wearable electronic equipment. In addition, the method using the conventional mechanical transmission has a disadvantage that the transmission mechanism is easily damaged when it is subjected to an impact force. Therefore, it is necessary and meaningful to find a thin power supply that can be embedded in a wearable electronic device to supply power to the electronic device while avoiding damage to the transmission mechanism due to impact.

Disclosure of Invention

The application provides a human kinetic energy collection device of embeddable wearable electronic equipment, and the device simple structure, the volume is less, weight is lighter to the slimming and the lightweight of battery have been realized. According to the application, the human body kinetic energy collecting device can be embedded into the wearable electronic equipment, and the human body movement biological mechanical energy can be converted into electric energy by utilizing the limb swinging of a person during normal activities. The human body kinetic energy collecting device utilizes magnetic transmission to replace mechanical transmission, so that mechanical friction is avoided, and conversion efficiency is improved. In addition, because the magnetic transmission is used for replacing the mechanical transmission, the human body kinetic energy collecting device can also avoid the damage of the transmission mechanism caused by the impact force caused by the sudden movement of the limbs of the human body.

According to one aspect of the present application, there is provided a human body kinetic energy collecting apparatus usable to embed a wearable electronic device. The human body kinetic energy collecting device can comprise a base, a first rotor, a heavy hammer, a second rotor, a modulation ring and a stator. The first rotor may be provided in a circular ring shape and may be coupled to the base. The first rotor is circumferentially rotatable relative to the base. A plurality of pairs of first permanent magnets may be disposed on a surface of the first rotor. The weight is coaxially fixed to the first rotor. The second rotor may be provided in a ring shape and may be connected to the base coaxially with the first rotor. The second rotor is circumferentially rotatable relative to the base. A plurality of pairs of second permanent magnets may be provided on a surface of the second rotor. The modulation ring may be fixed to the base concentrically with the first rotor between the first rotor and the second rotor. The stator is fixed to the base concentrically with the first rotor on a side of the second rotor opposite the first rotor. Coils may be disposed on the stator.

According to an exemplary embodiment of the present application, the weight may be provided, for example, as a ring having a central angle of less than 180 °.

According to an exemplary embodiment of the present application, the modulation ring may comprise a plurality of magnetically permeable blocks. The plurality of magnetic conductive blocks may be arranged in a ring shape along the same circumference. The plurality of magnetic conductive blocks may be integrally formed using, for example, numerical control machining, wire cutting, powder metallurgy, or 3D printing methods.

According to an exemplary embodiment of the present application, the first rotor may be a low speed rotor, and the second rotor may be a high speed rotor.

According to an exemplary embodiment of the application, the plurality of magnetically permeable blocks may be manufactured, for example, in blocks and may be filled with a hard material to enhance mechanical strength. The magnetic conduction blocks can also be arranged in a way that the central axes of the magnetic conduction blocks are obliquely arranged relative to the axis of the base so as to reduce the cogging torque.

According to an exemplary embodiment of the present application, the weight, the first rotor, the modulation ring, the second rotor, and the stator may be arranged to be concentrically arranged along an axial direction.

According to another exemplary embodiment of the present application, the weight, the first rotor, the modulation ring, the second rotor, and the stator may be arranged to be concentrically arranged along a radial direction.

According to an exemplary embodiment of the present application, the first rotor may be provided with a first guide groove coaxial therewith, and the second rotor may be provided with a second guide groove coaxial therewith. The base can be provided with a first matching guide groove matched with the first guide groove and a second matching guide groove matched with the second guide groove. The first rotor may include a first slider, such as a ball, disposed in a first space defined by the first guide groove and the first guide groove in cooperation, so that the first rotor is circumferentially rotated with respect to the stator. The second rotor may include a second slider such as a ball, and the second slider may be disposed in a second space defined by the second guide groove and the second guide groove in cooperation so that the second rotor is circumferentially rotated with respect to the stator.

According to an exemplary embodiment of the present application, the first slider and the second slider may be made of a low friction material such as ceramic, for example.

According to another exemplary embodiment of the present application, the first rotor may be provided with a first guide groove coaxial with the first rotor, and the second rotor may be provided with a second guide groove coaxial with the second rotor. The human body kinetic energy collecting device may further include a first stationary ring and a second stationary ring. The first stationary ring may be fixed on the base and may be provided with a first fitting guide groove to be fitted with the first guide groove. The first rotor is circumferentially rotatable relative to the base via the first stationary ring. The second stationary ring may be fixed on the base and may be provided with a second fitting guide groove to be fitted with the second guide groove. The second rotor is circumferentially rotatable relative to the base via the second stationary ring.

According to an exemplary embodiment of the present application, the first rotor may include a first slider such as a ball. The first slider may be disposed in a first space defined by the first guide groove and the first guide groove in cooperation so that the first rotor is circumferentially rotated with respect to the stator. The second rotor may comprise a second slide such as a ball. The second slider may be disposed in a second space defined by the second guide groove and the second guide groove in cooperation so that the second rotor is circumferentially rotated with respect to the stator.

According to an exemplary embodiment of the present application, the second permanent magnet may be arranged as a single row permanent magnet or a double row permanent magnet.

When arranged as a single row of permanent magnets, the number of pairs of the single row of permanent magnets is less than the number of pairs of the first permanent magnets. When arranged as double row permanent magnets, a magnetic field shielding ring is arranged between a first row of the double row permanent magnets and a second row of the double row permanent magnets, and the first row of permanent magnets cooperates with the second rotor. The logarithm of the first column of permanent magnets is smaller than the logarithm of the first permanent magnets.

According to an exemplary embodiment of the application, the first column of permanent magnets may for example be arranged to be magnetized in a radial direction, and the second column of permanent magnets may for example be arranged to be magnetized in an axial direction.

According to another exemplary embodiment of the application, the first column of permanent magnets and the second column of permanent magnets may for example be arranged to be both magnetized in a radial direction.

According to an exemplary embodiment of the present application, a slot may be provided on the stator, for example, and the coil may be wound in the slot.

According to a further exemplary embodiment of the application, the coil can be arranged on the stator, for example by means of a printed circuit.

According to one aspect of the application, a human body kinetic energy conversion method for embedding a wearable electronic device is provided. The method can comprise the following steps: acquiring a first kinetic energy exerted on the electronic device; generating a low-frequency magnetic field by using the kinetic energy; high-frequency modulating the low-frequency magnetic field to generate a high-frequency magnetic field; acquiring a second kinetic energy by using the high-frequency magnetic field; and generating an induced current using the second kinetic energy. The induced current generated can be stored in the batteries of various portable, wearable smart electronic devices or directly power the smart electronic devices.

According to the exemplary embodiment of the application, the mechanical energy of limb swing is acquired by the weight when the limb wearing the electronic device swings. The heavy punch drives the low-speed rotor to rotate, so that the permanent magnet on the low-speed rotor is utilized to convert the mechanical energy of limb swing into the energy of the low-frequency magnetic field. The generated low-frequency magnetic field is high-frequency modulated by a modulation loop to generate a high-frequency magnetic field. The high-frequency magnetic field drives the permanent magnet on the high-speed rotor to rotate, and then drives the high-speed rotor to rotate. The rotation of the permanent magnet on the high-speed rotor enables the winding coil on the stator to generate magnetic flux change, so that the mechanical energy of the swing of the human body limb is converted into electric energy.

According to an aspect of the present application, there is provided a wearable electronic device and a portable electronic device including the human body kinetic energy collecting apparatus according to the exemplary embodiments of the present application. The wearable electronic device can be, for example, a smart bracelet, smart glasses, a smart watch, a wearable health monitoring device, and the like. The portable electronic device may be, for example, a mobile phone, a tablet computer, a personal digital assistant, etc.

Drawings

The principles of the inventive concept are explained below by describing non-limiting embodiments of the present application in conjunction with the drawings. It is to be understood that the drawings are intended to illustrate exemplary embodiments of the application and not to limit the same. The accompanying drawings are included to provide a further understanding of the inventive concepts of the application, and are incorporated in and constitute a part of this specification. Like reference numerals in the drawings denote like features. In the drawings:

fig. 1 illustrates a cross-sectional view of a disassembled structure of a human body kinetic energy collecting device according to an exemplary embodiment of the present application;

fig. 2A to 2C are schematic views illustrating an arrangement of permanent magnets of a human body kinetic energy collecting device on a high-speed rotor according to an exemplary embodiment of the present application;

fig. 3 is a schematic sectional view illustrating a decomposition structure of a human body kinetic energy collecting apparatus according to another exemplary embodiment of the present application;

fig. 4 is a schematic cross-sectional view illustrating a disassembled structure of a human body kinetic energy collecting device according to still another exemplary embodiment of the present application;

fig. 5 shows a schematic diagram of a human body kinetic energy collection device embedded in a smart watch according to an exemplary embodiment of the present application; and

fig. 6 shows a schematic view of a human body kinetic energy collecting device embedded in a smart bracelet according to an exemplary embodiment of the present application.

Detailed Description

For a better understanding of the present application, various aspects of the present application will be described in more detail below with reference to exemplary embodiments shown in the drawings. It should be understood that the detailed description is merely illustrative of exemplary embodiments of the present application and does not limit the scope of the present application in any way. Like reference numerals refer to like elements throughout the specification. The expression "and/or" includes any and all combinations of one or more of the associated listed items.

It should be noted that in the present description and claims, the expressions first, second, etc. are used only for distinguishing one feature from another, and do not represent any limitation of the features. Thus, the first rotor, first guide slot discussed herein may also be referred to as a second rotor, second guide slot, and vice versa, without departing from the teachings of the present application.

In the drawings, the thickness, size, and shape of each component have been slightly exaggerated for convenience of explanation. Accordingly, the drawings are by way of example only and are not drawn to scale.

It will be understood that the terms "comprises," "comprising," "includes," "including," "has," "including," and/or "including," when used in this specification, specify the presence of stated features, elements, components, and/or steps, but do not preclude the presence or addition of one or more other features, elements, components, steps, and/or groups thereof. Moreover, when a statement such as "at least one of" appears after a list of listed features, the entirety of the listed features is modified rather than modifying individual elements in the list. Furthermore, when describing embodiments of the present application, the use of "may" mean "one or more embodiments of the present application. Also, the expression "exemplary" is intended to refer to or illustrate an example of an embodiment.

Unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the relevant art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.

The portable or wearable electronic devices to which the present application relates may include, but are not limited to, mobile phones, tablets, personal digital assistants, smart bands, smart glasses, smart watches, wearable health monitoring devices, and the like.

Various aspects of the present application will be described in more detail below with reference to the accompanying drawings in conjunction with specific embodiments, but the embodiments of the present application are not limited thereto.

As shown in fig. 1, the human body kinetic energy collecting device 10 embeddable wearable electronic apparatus may include a stationary base 106, a low-speed rotor 102 and a high-speed rotor 110 that are connected to the base 106 to be circumferentially rotatable with respect to the base 106, and a stator 108 that is fixed to the base 106 on a side of the high-speed rotor 110 opposite to the low-speed rotor 102. Stator 108 is fixed to base 106, whereby low-speed rotor 102 and high-speed rotor 110 are rotatable circumferentially relative to stator 108.

The weight 112 is fixedly connected to the low speed rotor 102 to rotate the rotor 102 relative to the stator 108 when the weight swings back and forth due to gravity.

The weight 112 can be designed as a ring with a central angle less than 180 °, but it should be understood that the weight can be designed as other shapes that can rotate the low speed rotor 102. To increase the moment of inertia, the weight 112 can be made of high-density material such as tungsten alloy, gold alloy, etc. In an exemplary embodiment, the weight 112 is fixed to the low-speed rotor 102 coaxially with the low-speed rotor 102. The weight 112 may be integrally formed with the low-speed rotor 102.

The low-speed rotor 102 may be provided in a ring shape, an inner surface of which may be attached with a greater number of pairs of permanent magnets 111, and an outer surface of which may be provided with a smooth guide groove 115. The low speed rotor 102 may also act as a rotating ring for the low speed bearing that is coaxially engaged with the low speed bearing stationary ring 104, which also has a smooth guide groove 116. The low speed bearing stationary ring 104 is fixed to a base 106. Movable devices 103, such as balls 103, roll within the space defined by the smooth guide grooves of low speed rotor 102 and the smooth guide grooves of low speed bearing stationary ring 104 to reduce mechanical friction.

The high-speed rotor 110 may be designed, for example, in a ring shape, and a plurality of permanent magnets 109 may be attached to a surface of the high-speed rotor 110. The permanent magnets 109 may be arranged as a single row of permanent magnets or as a double row of permanent magnets. When the permanent magnets of the high-speed rotor 110 are arranged in only a single row, the number of pairs of the row of permanent magnets of the high-speed rotor 110 is small compared to the permanent magnets of the low-speed rotor 102, which can simultaneously serve as a transmission mechanism coupled to the low-speed rotor 102 and an electromechanical conversion mechanism coupled to the stator 108. When the permanent magnets 109 of the high speed rotor are arranged in two rows, where one row of permanent magnets coupled with the low speed rotor has fewer logarithms than the permanent magnets of the low speed rotor 102, and the other row of permanent magnets has several logarithms. The two rows of permanent magnets are separated by magnetic field shielding material.

The permanent magnets 109 and 111 may be made of, for example, a rare earth permanent magnet material (neodymium iron boron Nd2Fe14B), samarium cobalt (SmCo), AlNiCo (AlNiCo), or a ferrite permanent magnet material, etc., but the present application is not limited thereto.

A modulation ring 105 is provided between the low-speed rotor 102 and the high-speed rotor 110. The modulation ring 105 may be formed of, for example, a plurality of magnetic conductive blocks uniformly distributed on the same circumference, and thus fixed to the base 106 in a ring shape between the low-speed rotor 102 and the high-speed rotor 110 for modulating the magnetic field. The magnetic permeability blocks of the modulation ring 105 may be fabricated integrally or in blocks, for example, using numerical control machining, wire cutting, powder metallurgy, or 3D printing. The magnetic conductive block may be made of, for example, pure iron (DT1), pure iron (DT2), pure iron (DT3), silicon steel (hot rolling), silicon steel (cold rolling grain orientation), 45 permalloy, 78 permalloy, super permalloy, superconducting alloy, superconducting compound, or the like. The magnetically permeable blocks of the modulation ring 105 may be filled with a hard material to enhance mechanical strength, or the central axis of the magnetically permeable blocks may be tilted at an angle relative to the axis of the base to reduce cogging torque.

According to an exemplary embodiment of the present application, the weight 112, the low speed rotor 102, the modulation ring 105, the high speed rotor 110 and the stator 108 are coaxially disposed on the base 106.

Fig. 2A to 2C are schematic views illustrating an arrangement of permanent magnets of a human body kinetic energy collecting device on a high-speed rotor according to an exemplary embodiment of the present application. In particular, fig. 2A shows a single row permanent magnet arrangement on a high speed rotor that can be used in the human kinetic energy harvesting device of the present application. As shown in fig. 2A, the permanent magnets 211 arranged in a single row are mounted on the high-speed rotor 212, which serves as both a transmission mechanism coupled with the low-speed rotor and an electromechanical conversion mechanism coupled with the stator. Fig. 2B shows a double row permanent magnet arrangement on a high speed rotor that can be used in the human kinetic energy harvesting device of the present application. As shown in fig. 2B, a first row of permanent magnets 221, a magnetic field shielding ring 222, and a second row of permanent magnets 223 are mounted on a high-speed rotor 224. The first row 221 and the second row 223 of permanent magnets are each magnetized in a radial direction. The first row of permanent magnets 211 may serve as a gear train coupled to the low speed rotor and the second row of permanent magnets 233 may serve as an electromechanical transducer coupled to the stator. Fig. 2C shows another double row permanent magnet arrangement that may be used on the high speed rotor of the human kinetic energy harvesting device of the present application. As shown in fig. 2C, a first row of permanent magnets 231, a magnetic field shielding ring 232, and a second row of permanent magnets 233 are mounted on a high-speed rotor 234. Unlike fig. 2B, the second column of permanent magnets 233 is magnetized in the axial direction.

The other surface of the high-speed rotor 110 may be provided with a smooth guide groove 117. In the exemplary embodiment shown in fig. 1, the high speed rotor 110 may simultaneously act as a rotating ring for the high speed bearing, which co-axially mates with the high speed bearing stationary ring 101, which also has smooth guide slots 118. The high-speed bearing stationary ring 101 is fixed to the base 106, and balls 119 may be disposed in a space defined between the smooth guide groove 117 of the high-speed rotor 110 and the smooth guide groove 118 of the high-speed bearing stationary ring 101 to allow the balls 119 to roll therebetween, thereby reducing mechanical friction.

The transmission mechanism consisting of the low speed rotor 102, the modulation ring 105 and the high speed rotor 110 can be considered a single stage step up transmission mechanism. It will be appreciated by those skilled in the art that the mechanism can also be designed as a multi-stage acceleration transmission based on the same principles, according to the requirements of a particular application, thereby further improving the acceleration ratio.

A stator 108 is fixedly mounted on the base 106 and provided with coils 107. In an exemplary embodiment, for example, the stator may be provided in a structure having slots so as to wind the coils in the slots of the stator. In an alternative embodiment, the stator may also be provided without a slot structure, and the coils may be manufactured and fixed to the stator, for example, by means of printed circuits or self-adhesive coils.

It should be understood that each of the above components may be mounted coaxially in either the radial or axial direction, as desired for different applications. The permanent magnets may be magnetized in a radial direction or an axial direction depending on the arrangement of the device.

The weight, low speed rotor, modulation ring, high speed rotor and stator are described above in detail by way of exemplary embodiments. Next, the human body kinetic energy collecting device according to the present application will be explained in its entirety.

Fig. 3 shows a cross-sectional view of an exploded structure of a human body kinetic energy collecting device 30 according to another exemplary embodiment of the present application. In this embodiment, a first column 309 and a second column 311 of permanent magnets are arranged on the high speed rotor 312. The two arrays of permanent magnets 309 and 311 and the field shield ring 310 are fixed to a high speed rotor 312. The first row of permanent magnets 309 serves as a transmission mechanism coupled to the low-speed rotor 302, and the second row of permanent magnets 311 serves as an electromechanical conversion mechanism coupled to the stator 308. As shown in fig. 3. The weight 314, the low-speed rotor 302, the modulation ring 305, the high-speed rotor 312 and the stator 308 are coaxially arranged in sequence along the radial direction. The stator 308 of this exemplary embodiment may employ a structure having a cogging. The coil 307 may be wound in the spline structure. Since the respective members are coaxially arranged in the radial direction, the thickness of the entire human body kinetic energy collecting device 30 is thin. Further, in this embodiment, since the respective components are arranged in the radial direction, the axial dimension can be small, thereby achieving the thinning of the human body kinetic energy collecting device 30 in the axial direction. The human body kinetic energy collecting device 30 according to this embodiment is adapted to be embedded in a flat-profile wearable electronic apparatus, for example.

Fig. 4 shows a cross-sectional view illustrating a disassembled structure of a human body kinetic energy collecting device 40 according to still another exemplary embodiment of the present application. The human body kinetic energy collecting device 40 shown in fig. 4 concentrically arranges the respective components in the axial direction. Specifically, the weight 406, the low-speed rotor 404, the modulation ring 407, the high-speed rotor 408, and the stator 409 are coaxially installed in this order along the axial direction. In this example, a single row of permanent magnets 401 is arranged on the high speed rotor 408. The stator 409 may employ a toothless slot structure. The coil 410 may be mounted on the stator 409 using, for example, a printed circuit. This embodiment has a small thickness in the radial direction of the entire device because the respective components are arranged in the axial direction, thereby achieving a thin profile of the human body kinetic energy collecting device 40 in the radial direction. The human body kinetic energy collecting device 40 according to this embodiment is suitable for embedding a wearable electronic device having a ring-like outer shape, for example.

Fig. 5 shows a schematic diagram of a human body kinetic energy collection device 504 embedded in a smart watch 500 according to an exemplary embodiment of the present application. As shown in fig. 5, the human body kinetic energy collecting device 504 according to the exemplary embodiment of the present application is coaxially arranged in a radial direction and embedded in the case 505 of the smart watch 500. Since the smart watch 500 generally requires a relatively thin axial thickness, the human kinetic energy collection device 504 according to the present application may be radially arranged to meet the requirements of the application. For example, the human kinetic energy collection device 504 may employ the embodiment shown in fig. 3.

The operation of the body kinetic energy collection device is described in detail herein with reference to the embodiment shown in fig. 3.

Since the person swings the arm at intervals in normal activities, the arm and the weight 314 form a double-swing structure. Driven by the inertia force, the weight 314 rotates around the axis of the base 306, and drives the low-speed rotor 302 connected thereto to rotate. When the array of permanent magnets 313 fixed on the surface of the low-speed rotor 302 rotates with the low-speed rotor 302, a high-frequency magnetic field is generated under the action of the modulation ring 305, and the high-speed rotor 312 with the permanent magnets 311 fixed on the surface is driven to rotate. Since the number of pairs of the permanent magnets 313 on the low-speed rotor 302 is larger than the number of pairs of the permanent magnets 311 on the surface of the high-speed rotor 312, the rotation of the high-speed rotor 312 is accelerated, thereby obtaining a higher rotation speed. When the rotor rotates, the permanent magnet 309 on the high-speed rotor 312 simultaneously changes the magnetic flux of the winding coil 307 on the stator 308, so that the mechanical energy of the human body limb swing is converted into electric energy. The generated electric energy is rectified and regulated by a circuit 503 connected with the intelligent watch circuit, and can be directly used for supplying power for the application 501 of the intelligent watch 500 or stored in a battery 502.

Fig. 6 shows a schematic view of a human body kinetic energy collecting device 602 embedded in a smart bracelet 600 according to an exemplary embodiment of the present application. As shown in fig. 6, a human body kinetic energy collecting device 602 according to an exemplary embodiment of the present application is coaxially arranged in an axial direction and embedded in a case 601 of a smart bracelet 600. Since smart bracelets generally require a relatively thin radial thickness, the human kinetic energy collection device 602 may be axially arranged to meet the radial ultra-thinning requirements of the application. The human body kinetic energy collecting device for the smart band 600, for example, may employ the embodiment shown in fig. 4.

The operation of the human body kinetic energy collecting device for the smart band 600 will be described in detail with reference to the embodiment shown in fig. 4.

When the arm is swung, the weight 406 of the human body kinetic energy collecting device 40 rotates around the axis of the base 402 under the driving of the inertia force, and simultaneously drives the low speed rotor 404 connected with the weight to rotate. When the array of permanent magnets 405 fixed on the surface of the low-speed rotor 404 rotates, a high-frequency magnetic field is generated under the action of the modulation ring 407, thereby driving the high-speed rotor 408 with the permanent magnets 401 fixed on the surface to rotate. Since the number of pairs of the permanent magnets 405 on the low-speed rotor 404 is larger than the number of pairs of the permanent magnets 401 on the surface of the high-speed rotor 408, the rotation of the high-speed rotor 408 is accelerated, and thus a higher rotation speed is obtained. When rotating, the permanent magnet 401 on the high-speed rotor 408 causes the winding coil 410 on the stator 409 to generate magnetic flux changes, thereby converting the mechanism of human limb swinging into electric energy. The generated electric energy is connected to the circuit 603 of the smart band, and after being rectified and voltage-regulated, the generated electric energy can be directly supplied to the application 604 of the smart band 600 or stored in a battery (not shown in the figure).

Thus, the human body kinetic energy collecting device of the embeddable intelligent electronic device according to the present application can generate electric energy for directly supplying power to an application of the intelligent electronic device or storing in a battery by: when the limb wearing the electronic equipment swings, acquiring the mechanical energy of the swinging of the limb through a heavy hammer; the heavy punch drives the low-speed rotor to rotate, so that the permanent magnet on the low-speed rotor cuts magnetic lines of force to convert the mechanical energy of limb swing into first induced current; modulating the generated first induced current at high frequency by using a modulation loop to generate a high-frequency magnetic field; the high-frequency magnetic field drives the permanent magnet on the high-speed rotor to rotate so as to drive the high-speed rotor to rotate; the rotation of the permanent magnet on the high-speed rotor causes the winding coil on the stator to generate magnetic flux change, thereby converting the mechanism of the swing of the human limb into electric energy.

Exemplary embodiments of the present application are described above with reference to the accompanying drawings. It should be understood by those skilled in the art that the above-described embodiments are merely examples for illustrative purposes and are not intended to limit the scope of the present application. The scope of the application should be determined with reference to the appended claims and their equivalents. Any modifications, equivalents and the like which come within the teachings of this application and the scope of the claims should be considered to be within the scope of this application.