CN116054524A - Motion power generation equipment and wearable motion power generation dress - Google Patents

Abstract

The application discloses sports power generation equipment and wearable sports power generation clothing. The equipment consists of a magnetic device, a plurality of groups of coils and a plurality of groups of connecting circuits; wherein, the magnetic device is fixed on the human body and used for generating a magnetic field; the plurality of groups of coils are respectively sleeved on the limbs of the human body, and when the human body moves, the relative position of each group of coils and the magnetic device is changed, so that the magnetic flux passing through each group of coils is changed to generate induction current; the two ends of each group of coils are respectively connected with a group of connecting circuits, and each group of connecting circuits is used for being connected with the power input end of electric equipment or an electric energy storage component. This application is produced the electric energy by human self motion, can produce induced current at the in-process of motion every coil of group, has solved portable electronic product's power supply problem, need not to charge in advance, has avoided the precious defect that can't use when forgetting to charge, need not consider external environmental factors such as weather, has overcome the power supply unit who adopts photovoltaic technology and has easily been limited to the problem of weather.

Description

Motion power generation equipment and wearable motion power generation dress

Technical Field

The application relates to the technical field of generators, in particular to sports power generation equipment and wearable sports power generation clothes.

Background

With the development of communication and electronic technologies, electronic products carried by people are increasing. The electronic products provide great convenience for the travel, communication and health of people, and become an indispensable article for the life of modern people. When the electronic product is in low electric quantity, people often anxiety about the electric quantity of the electronic product, so when people go out far away, a portable power supply device is often needed to cope with the situation of the sudden electric quantity shortage of the electronic product.

Although the charging device can solve the dilemma to a certain extent, the charging device cannot generate electricity and has the problem of forgetting to charge; for example, people meet danger in the open air or the field and need electronic products to contact outwards, and electronic products electricity consumption is done and just the treasured that charges also is because forgetting to charge when not having the electric quantity, people often have difficulty in finding other charging devices and charge for electronic products this moment. Although the power supply device adopting the photovoltaic technology can automatically generate power and can better cope with unexpected situations, when the power supply device is used, the photovoltaic panel is required to be made to be right against sunlight to generate enough electric energy, and enough electric quantity is generally difficult to generate under the condition of dark weather; moreover, due to the problem of conversion efficiency, the power supply device adopting the photovoltaic technology must have a sufficient photosensitive area, so that the power supply device adopting the photovoltaic technology is often large in size, and the carrying burden is increased for people.

Disclosure of Invention

For this reason, this application provides a motion power generation facility and wearable motion electricity generation dress to the precious unable self-generation that charges that solves prior art existence forgets unable use when charging, and adopt photovoltaic technology's power supply unit easily to be limited to the technical problem of weather.

In order to achieve the above object, the present application provides the following technical solutions:

in a first aspect, a sports power generating apparatus includes:

a magnetic device fixed on the human body for generating a magnetic field;

the coils are respectively sleeved on the limbs of the human body; when a human body moves, the relative positions of each group of coils and the magnetic device are changed, so that the magnetic flux passing through each group of coils is changed;

and the two ends of each group of coils are respectively and electrically connected with one group of connecting circuits, and each group of connecting circuits is used for being electrically connected with the power input end of the electric equipment.

Optionally, the magnetic device is one or more strip-shaped neodymium iron boron magnets, each group of coils is a copper coil or an aluminum coil with an insulating layer on the surface, and each group of connecting circuits is a telescopic copper wire or an aluminum wire with an insulating layer on the surface.

Optionally, the magnetic device is fixed on the waist, chest or back of the human body.

Optionally, the motion power generation device further includes:

and each group of connecting circuits is electrically connected with the input end of the alternating-direct conversion component, and the output end of the alternating-direct conversion component is electrically connected with the power input end of the electric equipment.

In a second aspect, a sports power generating apparatus includes:

a magnetic device fixed on the human body for generating a magnetic field;

the coils are respectively sleeved on the limbs of the human body; when a human body moves, the relative positions of each group of coils and the magnetic device are changed, so that the magnetic flux passing through each group of coils is changed;

and the two ends of each group of coils are respectively and electrically connected with one group of connecting circuits, and each group of connecting circuits is also electrically connected with the power input end of the electric energy storage component.

Optionally, the electrical energy storage assembly is secured to the back of the human body.

Optionally, the electrical energy storage assembly comprises:

each group of connecting circuits is electrically connected with the input end of the alternating-current-direct-current conversion component;

and the input end of the storage battery is electrically connected with the output end of the alternating-current-direct-current conversion assembly, and the output end of the storage battery is electrically connected with the power input end of the electric equipment.

In a third aspect, a wearable athletic power generation garment includes:

a garment body;

the magnetic device is fixed on the clothing body and is used for generating a magnetic field;

the plurality of groups of coils are respectively embedded in sleeves and trouser legs of the clothing body; when a human body wearing the clothing body moves, the relative positions of each group of coils and the magnetic device are changed, so that the magnetic flux passing through each group of coils is changed;

the two ends of each group of coils are respectively and electrically connected with one group of connecting circuits; each group of connecting circuits is used for being electrically connected with the power input end of the electric equipment, or each group of connecting circuits is also electrically connected with the power input end of the electric energy storage component.

Optionally, the clothing body comprises a coat and trousers, or the clothing body is a one-piece garment.

Compared with the prior art, the application has the following beneficial effects:

1. the application provides a motion power generation device which consists of a magnetic device, a plurality of groups of coils and a plurality of groups of connecting circuits; wherein, the magnetic device is fixed on the human body and used for generating a magnetic field; the plurality of groups of coils are respectively sleeved on the limbs of the human body, and when the human body moves, the relative position of each group of coils and the magnetic device is changed, so that the magnetic flux passing through each group of coils is changed to generate induction current; the two ends of each group of coils are respectively and electrically connected with a group of connecting circuits, and each group of connecting circuits is used for being electrically connected with the power input end of the electric equipment. After the human body wears the motion power generation equipment, each group of coils can generate induction current in the motion process and transmit the induction current to the electric equipment in real time through the corresponding connection circuit, so that the electric equipment can be powered while generating electricity, and the power supply problem of the portable electronic product is solved; the motion power generation equipment generates electric energy by the motion of a human body, does not need to charge in advance, and avoids the defect that a charger cannot be used when forgetting to charge; the power generation equipment can generate electric energy to supply power to electronic products when a human body only needs to exercise at any time, and external environmental factors such as weather do not need to be considered, so that the problem that a power supply device adopting a photovoltaic technology is easily limited by weather is solved.

2. The connecting circuit is telescopic, and the setting position of each group of coils on the limbs of a human body can be conveniently adjusted, so that the exercise power generation equipment can be matched with people with different body types and heights.

Drawings

For a more visual illustration of the prior art and the present application, several exemplary drawings are presented below. It should be understood that the specific shape and configuration shown in the drawings should not be considered in general as limiting upon the practice of the present application; for example, based on the technical concepts and exemplary drawings disclosed herein, those skilled in the art have the ability to easily make conventional adjustments or further optimizations for the add/subtract/assign division, specific shapes, positional relationships, connection modes, dimensional scaling relationships, etc. of certain units (components).

Fig. 1 is a schematic structural diagram of a sports power generation device according to a first embodiment of the present application;

fig. 2 is a schematic diagram of a circuit connection relationship of a motion power generation device according to a first embodiment of the present application;

fig. 3 is a schematic diagram of a complete circuit connection relationship of a sports power generation device according to a first embodiment of the present application;

fig. 4 is a schematic diagram of a circuit connection relationship of another exercise power generation device according to the second embodiment of the present application;

fig. 5 is a schematic diagram of a complete circuit connection relationship of another exercise power generation device according to the second embodiment of the present application.

Reference numerals illustrate:

1. a magnetic device; 2. a coil; 3. a connection circuit; 4. an electric device; 5. an AC-DC conversion assembly; 6. an electrical energy storage assembly; 7. and a storage battery.

Detailed Description

The present application is further described in detail below with reference to the attached drawings.

In the description of the present application: unless otherwise indicated, the meaning of "a plurality" is two or more. The terms "first," "second," "third," and the like in this application are intended to distinguish between the referenced objects without a special meaning in terms of technical connotation (e.g., should not be construed as emphasis on degree or order of importance, etc.). The expressions "comprising", "including", "having", etc. also mean "not limited to" (certain units, components, materials, steps, etc.).

The terms such as "upper", "lower", "left", "right", "middle", and the like, as referred to in this application, are generally used for convenience in visual understanding with reference to the drawings, and are not intended to be an absolute limitation of the positional relationship in actual products. Such changes in relative positional relationship are considered to be within the scope of the present description without departing from the technical concepts disclosed herein.

Example 1

In the present embodiment, as shown in fig. 1, there is provided a sports power generating apparatus including:

the magnetic device 1 is fixed on a human body, and the magnetic device 1 is used for generating a constant magnetic field;

a plurality of groups of coils 2 respectively sleeved on the limbs of the human body in a surrounding way and used for generating electricity through movement; when a human body moves, along with the swing of limbs, the relative positions of each group of coils 2 and the magnetic device 1 are changed, so that the magnetic flux passing through each group of coils 2 is changed, and induced current can be generated in each group of coils 2;

the multiple groups of connection circuits 3 are arranged on a human body, as shown in fig. 2, two ends of each group of coils 2 are respectively and electrically connected with one end of one group of connection circuits 3, and the other end of each group of connection circuits 3 is used for being electrically connected with a power input end of electric equipment 4.

Specifically, the coils 2 are provided with 4 groups, and two ends of each group of coils 2 are connected into the electric equipment 4 through a group of connecting circuits 3, that is, the connecting circuits 3 are provided with 8 groups. Each coil 2 and the corresponding two groups of connecting circuits 3 and electric equipment 4 at the rear stage form a closed loop together, and because of the electromagnetic induction principle, a human body drives each group of coils 2 to cut magnetic force lines when moving, and current is generated in the loop; the connection circuit 3 is responsible for leading the induction current generated by each group of coils 2 on the limbs to the electric equipment 4 at the later stage so as to supply power for the electric equipment 4.

According to the law of electromagnetic induction, when a person walks or runs, each set of coils 2 fitted around the limbs changes in relative position with the magnetic device 1, so that the magnetic flux passing through each set of coils 2 changes, thereby inducing an electric field in each set of coils 2. The specific formula is as follows:

/>

wherein epsilon is the generated electromotive force, n is the number of turns of the coil, B is the magnetic induction intensity of the position where the coil is positioned,

indicating the rate of change of the area of the coil facing the magnetic field. Thus, the faster the speed of walking or running, the more power is generated.

Wherein the magnetic device 1 can be fixed on the human body perpendicular to the ground. Of course, in special cases, it may also be arranged parallel to the ground. The electric equipment 4 can be a common electronic product or other electric equipment; for example, several LED lamps provided on the garment. The setting position of the electric device 4 is not limited, and fig. 1 shows only an exemplary setting position of the electric device 4 according to what product the electric device 4 is in particular.

In the motion process, after the connecting circuit 3 is connected with the power input end of the electric equipment 4, the induction current generated by each group of coils 2 can be transmitted to the electric equipment 4 in real time along the connecting circuit 3, so that electricity can be generated while the electric equipment 4 is supplied with electricity. For example, when the consumer 4 is embodied as an LED lamp, the LED lamp may be flashed with the generated electricity while walking to be able to temporarily illuminate the user when needed.

Further, the magnetic device 1 may be one or more strip-shaped neodymium iron boron magnets, and the magnetic device 1 may be fixed on the waist, chest or back of the human body vertically; each group of coils 2 is a copper coil or an aluminum coil with an insulating layer on the surface; each set of connection circuits 3 is a telescopic copper wire or an aluminum wire with an insulating layer on the surface. The connecting circuit 3 is telescopic, so that the setting position of each group of coils 2 on the limbs of a human body can be conveniently adjusted, and the exercise power generation equipment can be matched with people with different body types and heights; the distance between the electric equipment 4 and each group of coils 2 is not worried, and the electric equipment 4 and each group of coils 2 can be used at a small distance.

Further, the magnetic field of the magnetic device 1 is a loop from the N pole to the S pole, and diverges outward, and the farther from the magnetic device 1, the smaller the magnetic induction. In order to ensure that the magnetic induction of each set of coils 2 is sufficiently high, the magnetic means 1 used should preferably be sufficiently strong. In practical applications, the surface magnetic field strength of the magnetic device 1 may be specifically set according to the number of turns of the coils 2, the distance between each set of coils 2, the actual power of the electric equipment 4, and the like.

Further, in specific use, for the dc electric device, the generated electricity may need to be used after ac-dc conversion and voltage change, so as shown in fig. 3, the motion power generation device may further include:

the other end of each group of connecting circuits 3 of the alternating current-direct current conversion assembly 5 is electrically connected with the input end of the alternating current-direct current conversion assembly 5, and the output end of the alternating current-direct current conversion assembly 5 is electrically connected with the power input end of the electric equipment 4.

The current generated by each group of coils 2 can supply power to the electric equipment 4 in real time after alternating current-direct current conversion, wherein the alternating current-direct current conversion component 5 can be a rectifier or a bridge rectifier circuit.

Of course, in practical applications, for different electric devices 4, other media or conversion devices may be further disposed between each set of connection circuits 3 and the electric device 4 to stably guide electricity generated by the coil 2 to the electric device 4, but this does not relate to the core invention point of the present application and is common knowledge of those skilled in the art, so that the present application will not be repeated for other situations.

The application provides a motion power generation device which consists of a magnetic device, a plurality of groups of coils and a plurality of groups of connecting circuits; wherein, the magnetic device is fixed on the human body and used for generating a magnetic field; the plurality of groups of coils are respectively sleeved on the limbs of the human body, and when the human body moves, the relative position of each group of coils and the magnetic device is changed, so that the magnetic flux passing through each group of coils is changed to generate induction current; the two ends of each group of coils are respectively and electrically connected with a group of connecting circuits, and each group of connecting circuits is used for being electrically connected with the power input end of the electric equipment. After the power generation equipment for sports is worn by a human body, each group of coils can generate induction current in the process of sports and transmit the induction current to electric equipment in real time through a corresponding connection circuit, so that power can be supplied to the electric equipment while power generation is performed, and the power supply problem of portable electronic products is solved. The motion power generation equipment generates electric energy by the motion of a human body, does not need to charge in advance, and avoids the defect that a charger cannot be used when forgetting to charge; the power generation equipment can generate electric energy to supply power to electronic products when a human body only needs to exercise at any time, and external environmental factors such as weather do not need to be considered, so that the problem that a power supply device adopting a photovoltaic technology is easily limited by weather is solved.

The wearable sports power generation equipment solves the technical problem of portable self-power generation of a human body, can be used for supplying power to electronic products carried by people, and avoids anxiety caused by no power supply to the electronic products when people go out.

Example two

In the present embodiment, there is provided another exercise power generating apparatus including:

the magnetic device 1 is fixed on a human body, and the magnetic device 1 is used for generating a constant magnetic field;

a plurality of groups of coils 2 respectively sleeved on the limbs of the human body in a surrounding way and used for generating electricity through movement; when a human body moves, along with the swing of limbs, the relative positions of each group of coils 2 and the magnetic device 1 are changed, so that the magnetic flux passing through each group of coils 2 is changed, and induced current can be generated in each group of coils 2;

the multiple groups of connection circuits 3 are arranged on a human body, as shown in fig. 4, two ends of each group of coils 2 are respectively and electrically connected with one end of one group of connection circuits 3, the other end of each group of connection circuits 3 is electrically connected with a power input end of an electric energy storage component 6, and a power output end of the electric energy storage component 6 is used for being electrically connected with electric equipment 4.

The schematic structure of the motion power generation device may refer to fig. 1, and the electric equipment 4 illustrated in fig. 1 may be replaced by an electric energy storage assembly 6, where the electric energy storage assembly 6 may be, but is not limited to, fixed on the back of a human body.

Specifically, similar to the exercise power generation apparatus provided in the first embodiment, the coils 2 are provided with 4 sets in total, and both ends of each set of coils 2 are connected to the electric energy storage module 6 via one set of connection circuits 3, that is, the connection circuits 3 are provided with 8 sets in total. Each coil 2 and the corresponding two groups of connecting circuits 3 and the electric energy storage component 6 at the later stage form a closed loop together, and because of the electromagnetic induction principle, the human body drives each group of coils 2 to cut magnetic force lines when moving, and current is generated in the loop. In the movement process, the connection circuit 3 is responsible for guiding the induction current generated by each group of coils 2 on the limbs to the electric energy storage component 6 at the rear stage for storage in real time, so that after the electric energy storage component 6 is connected with the electric equipment 4, the electric energy stored in the electric energy storage component 6 can supply power for the electric equipment 4.

Further, as shown in fig. 5, the electrical energy storage assembly 6 may include:

the other end of each group of connecting circuits 3 is electrically connected with the input end of the alternating-current-direct-current conversion component 5;

and the input end of the storage battery 7 is electrically connected with the output end of the AC-DC conversion assembly 5, and the output end of the storage battery 7 is electrically connected with the power input end of the electric equipment 4.

So that the consumer 4 can be powered after the output of the battery 7 has been connected to the power input of the consumer 4. The ac-dc conversion component 5 may be a rectifier or a bridge rectifier circuit.

Further, the magnetic device 1 may be one or more strip-shaped neodymium iron boron magnets, and the magnetic device 1 may be fixed on the waist, chest or back of the human body vertically; each group of coils 2 is a copper coil or an aluminum coil with an insulating layer on the surface; each set of connection circuits 3 is a telescopic copper wire or an aluminum wire with an insulating layer on the surface. The connecting circuit 3 is telescopic, so that the setting position of each group of coils 2 on the limbs of a human body can be conveniently adjusted, and the exercise power generation equipment can be matched with people with different body types and heights; there is no concern about the distance of the electrical energy storage assembly 6 from each set of coils 2, and the electrical energy storage assembly 6 may be used at a slightly greater distance from each set of coils 2.

Further, the magnetic field of the magnetic device 1 is a loop from the N pole to the S pole, and diverges outward, and the farther from the magnetic device 1, the smaller the magnetic induction. In order to ensure that the magnetic induction of each set of coils 2 is sufficiently high, the magnetic means 1 used should preferably be sufficiently strong. In practical applications, the surface magnetic field strength of the magnetic device 1 may be specifically set according to the number of turns of the coils 2, the distance between each set of coils 2, the actual power of the electric equipment 4, and the like.

The application provides a motion power generation device which consists of a magnetic device, a plurality of groups of coils and a plurality of groups of connecting circuits; wherein, the magnetic device is fixed on the human body and used for generating a magnetic field; the plurality of groups of coils are respectively sleeved on the limbs of the human body, and when the human body moves, the relative position of each group of coils and the magnetic device is changed, so that the magnetic flux passing through each group of coils is changed to generate induction current; the two ends of each group of coils are respectively and electrically connected with a group of connecting circuits, and each group of connecting circuits is also electrically connected with the power input end of the electric energy storage component. After the human body wears the motion power generation equipment, each group of coils can generate induction current and store through the electric energy storage component in the motion process, and then after the electric energy storage component is connected with electric equipment, the power can be supplied to the electric equipment, and the power supply problem of portable electronic products is solved. The motion power generation equipment generates electric energy by the motion of a human body, does not need to charge in advance, and avoids the defect that a charger cannot be used when forgetting to charge; the power generation equipment can generate electric energy to supply power to electronic products when a human body only needs to exercise at any time, and external environmental factors such as weather do not need to be considered, so that the problem that a power supply device adopting a photovoltaic technology is easily limited by weather is solved.

In a third embodiment of the present invention,

in this embodiment, there is provided a wearable sports power generation garment, as shown in fig. 1, including:

a garment body; the dress body can be a separated coat and trousers or a one-piece coat;

the magnetic device 1 is fixed on the clothing body, and the magnetic device 1 is used for generating a constant magnetic field; after the dress body is worn by a human body, the magnetic device 1 can be vertical to the ground;

the plurality of groups of coils 2 are respectively embedded in sleeves and trouser legs of the clothing body and are used for generating electricity through movement; when a human body wearing the clothing body moves, the relative positions of each group of coils 2 and the magnetic device 1 are changed along with the swing of limbs, so that the magnetic flux passing through each group of coils 2 is changed, and thus, induced current can be generated in each group of coils 2;

the plurality of groups of connecting circuits 3 are arranged on the clothing body, and two ends of each group of coils 2 are respectively and electrically connected with one end of one group of connecting circuits 3; the other end of each group of connection circuits 3 is used for being electrically connected with the power input end of the electric equipment 4, or the other end of each group of connection circuits 3 is also electrically connected with the power input end of the electric energy storage component 6.

Specifically, similar to the movement power generation apparatus provided in the first and second embodiments, the coils 2 are provided with 4 sets in total, and both ends of each set of coils 2 are connected to the electric device 4 via one set of connection circuits 3, that is, the connection circuits 3 are provided with 8 sets in total. Each coil 2 and the corresponding two groups of connecting circuits 3 and the electric equipment 4 at the later stage form a closed loop together, and because of the electromagnetic induction principle, the human body drives each group of coils 2 to cut magnetic force lines when moving, and current is generated in the loop.

In the motion process, after the connecting circuit 3 is connected with the power input end of the electric equipment 4, the connecting circuit 3 is responsible for guiding the induction current generated by each group of coils 2 on the four limbs to the electric equipment 4 at the later stage in real time so as to supply power to the electric equipment 4, so that electricity can be generated at one side and the electric equipment 4 can be supplied with power at the same time. Or:

if the other end of the connection circuit 3 is electrically connected to the power input end of the electrical energy storage component 6, the connection circuit 3 is responsible for guiding the induced current generated by each set of coils 2 on the limbs to the electrical energy storage component 6 at the rear stage for storage in real time, so that after the electrical energy storage component 6 is connected with the electrical equipment 4, the electrical energy stored in the electrical energy storage component 6 can supply power to the electrical equipment 4.

The application provides wearable sports power generation clothing, which consists of a clothing body, a magnetic device, a plurality of groups of coils and a plurality of groups of connecting circuits; wherein, the magnetic device is fixed on the clothing body and used for generating a magnetic field; the plurality of groups of coils are respectively embedded in sleeves and trouser legs of the clothing body, and when a human body wearing the clothing body moves, the relative position of each group of coils and the magnetic device is changed, so that the magnetic flux passing through each group of coils is changed to generate induction current; two ends of each group of coils are respectively and electrically connected with one group of connecting circuits; each group of connecting circuits is used for being electrically connected with the power input end of the electric equipment, or each group of connecting circuits is also electrically connected with the power input end of the electric energy storage component. After the human body wears the sports power generation clothes, or in the process of sports, each group of coils can generate induction current and transmit the induction current to the electric equipment in real time through the corresponding connection circuit, so that power can be supplied to the electric equipment while power is generated; or each group of coils can generate induced current in the movement process and store the induced current through the electric energy storage component, and then after the electric energy storage component is connected with electric equipment, the electric equipment can be powered. The wearable sports power generation garment generates electric energy by the movement of a human body, and the garment does not need to be charged in advance, so that the defect that a charger cannot be used when forgetting to charge is avoided; the human body can generate electric energy to supply power to the electronic product only by wearing the clothes body and doing sports at any time, and the external environment factors such as weather do not need to be considered, so that the problem that the power supply device adopting the photovoltaic technology is easily limited by weather is solved.

The wearable sports power generation garment solves the technical problem of portable self-power generation of a human body, can be used for supplying power to electronic products carried by people, and avoids anxiety caused by no power supply to the electronic products when people go out.

Any combination of the technical features of the above embodiments may be performed (as long as there is no contradiction between the combination of the technical features), and for brevity of description, all of the possible combinations of the technical features of the above embodiments are not described; these examples, which are not explicitly written, should also be considered as being within the scope of the present description.

The foregoing has outlined and detailed description of the present application in terms of the general description and embodiments. It should be appreciated that numerous conventional modifications and further innovations may be made to these specific embodiments, based on the technical concepts of the present application; but such conventional modifications and further innovations may be made without departing from the technical spirit of the present application, and such conventional modifications and further innovations are also intended to fall within the scope of the claims of the present application.

Claims (9)

1. A sports power generating apparatus, characterized by comprising:

a magnetic device fixed on the human body for generating a magnetic field;

the coils are respectively sleeved on the limbs of the human body; when a human body moves, the relative positions of each group of coils and the magnetic device are changed, so that the magnetic flux passing through each group of coils is changed;

and the two ends of each group of coils are respectively and electrically connected with one group of connecting circuits, and each group of connecting circuits is used for being electrically connected with the power input end of the electric equipment.

2. The exercise power generation device of claim 1, wherein the magnetic means is one or more strip-shaped neodymium-iron-boron magnets, each set of coils is a copper coil or an aluminum coil with an insulating layer on the surface, and each set of connection circuits is a telescopic copper wire or an aluminum wire with an insulating layer on the surface.

3. The exercise power generation apparatus of claim 1, wherein the magnetic device is fixed to a waist, a chest or a back of a human body.

4. The exercise power plant of claim 1, further comprising:

and each group of connecting circuits is electrically connected with the input end of the alternating-direct conversion component, and the output end of the alternating-direct conversion component is electrically connected with the power input end of the electric equipment.

5. A sports power generating apparatus, characterized by comprising:

a magnetic device fixed on the human body for generating a magnetic field;

the coils are respectively sleeved on the limbs of the human body; when a human body moves, the relative positions of each group of coils and the magnetic device are changed, so that the magnetic flux passing through each group of coils is changed;

and the two ends of each group of coils are respectively and electrically connected with one group of connecting circuits, and each group of connecting circuits is also electrically connected with the power input end of the electric energy storage component.

6. The exercise power generation apparatus of claim 5 wherein the electrical energy storage assembly is secured to the back of the human body.

7. The exercise power generation apparatus of claim 5, wherein the electrical energy storage assembly comprises:

each group of connecting circuits is electrically connected with the input end of the alternating-current-direct-current conversion component;

and the input end of the storage battery is electrically connected with the output end of the alternating-current-direct-current conversion assembly, and the output end of the storage battery is electrically connected with the power input end of the electric equipment.

8. A wearable athletic power generation garment, comprising:

a garment body;

the magnetic device is fixed on the clothing body and is used for generating a magnetic field;

the plurality of groups of coils are respectively embedded in sleeves and trouser legs of the clothing body; when a human body wearing the clothing body moves, the relative positions of each group of coils and the magnetic device are changed, so that the magnetic flux passing through each group of coils is changed;

the two ends of each group of coils are respectively and electrically connected with one group of connecting circuits; each group of connecting circuits is used for being electrically connected with the power input end of the electric equipment, or each group of connecting circuits is also electrically connected with the power input end of the electric energy storage component.

9. The wearable athletic power generation garment of claim 8, wherein the garment body comprises a coat and pants or the garment body is a coverall.

Images