CN215267963U - Power generation device - Google Patents

Abstract

The utility model provides a power generation device, the primary structure includes a power component, power component is connected with a main rotation piece, a first accumulate device, a second accumulate device, and a processing element, main rotation piece can drive a passive rotation piece rotatory, second accumulate device then includes plural reverse protection circuit base plate, plural overload protection circuit base plate, and an electric power storage device, passive rotation piece then is connected with a power amplification subassembly, the power amplification subassembly includes an outer ring spare, plural outer meshing piece, and an inner meshing piece, the inner meshing piece is connected with a power generation subassembly, borrow this to strengthen the power generation effect of power generation subassembly via the power amplification subassembly, with the availability factor that cooperation second accumulate device increases the power.

Description

Power generation device

Technical Field

The utility model relates to a power generation facility indicates a power generation facility that power availability factor is better especially.

Background

Transportation tools are indispensable in human life all the time. Because of this, the tools for transportation will be developed continuously with the age, and vehicles and airplanes, which have evolved from ancient horses and carriages to industrial revolution, are used to replace manpower as transportation tools.

In modern life, vehicles, which generally use gasoline as a power source, are also gradually driven to electric power. The electric vehicle has the environment-friendly effect of not discharging waste gas, and has the efficiency of accelerating at low speed compared with that of a common gasoline engine vehicle, and the pure electric vehicle can still make the motor static when idling and parking so as to reduce the energy consumption. And the electric vehicle is particularly suitable for running in the current crowded cities due to the advantages of the electric vehicle.

However, since the energy required by the electric vehicle is provided by the battery, the service life of the electric vehicle is naturally inseparable from the battery, and if the power supply of the battery is insufficient, the trouble of using the electric vehicle is greatly increased.

In addition, although the electric vehicle technology related to the recovery of kinetic energy is available in the market, the kinetic energy generated during the movement can be recovered only during the sliding, and the use efficiency of the power supply is quite limited.

Therefore, how to solve the above-mentioned problems and disadvantages is the direction in which the applicant of the present invention and the related manufacturers engaged in the industry need to research and improve.

SUMMERY OF THE UTILITY MODEL

Therefore, in view of the above-mentioned shortcomings, the inventor of the present invention has devised a power generation device with better power utilization efficiency by collecting relevant data, evaluating and considering them in many ways, and continuously trying and modifying them according to years of experience accumulated in the industry.

The utility model discloses a main aim at: the power amplification assembly is utilized to enhance the power generation efficiency of the power generation assembly, and further the overall use efficiency is increased.

To achieve the above object, the present invention provides a power generation device, which mainly comprises:

a power element;

the main rotating piece is arranged at one side of the power element and is connected with the power element so as to drive the main rotating piece to act through the power element;

the driven rotating piece is arranged at one side of the main rotating piece and is connected with the main rotating piece so as to be driven to rotate by the action effect of the main rotating piece;

the first power storage device is arranged at one side of the power element and is electrically connected with the power element;

the second electricity storage device is arranged at one side of the power element and is electrically connected with the power element and the first electricity storage device, the second electricity storage device comprises a plurality of reverse protection circuit substrates, a plurality of overload protection circuit substrates and an electricity storage device, the plurality of overload protection circuit substrates are arranged at one side of the plurality of reverse protection circuit substrates and are respectively and electrically connected with the plurality of reverse protection circuit substrates, the electricity storage device is arranged at one side of the plurality of overload protection circuit substrates and is electrically connected with the plurality of overload protection circuit substrates, and the electricity storage device is internally provided with a plurality of capacitors which are mutually connected in series;

the power amplification assembly is connected with the driven rotating part and comprises an outer ring piece, a plurality of outer meshing pieces which are arranged in the outer ring piece and are meshed with the outer ring piece, and an inner meshing piece which is arranged at the center of the outer ring piece and is meshed with the outer meshing pieces respectively, wherein the outer ring piece is driven by the driven rotating part to rotate;

the power generation assembly is arranged at one side of the power amplification assembly and is connected with the internal engagement element so as to generate power through the rotation effect of the internal engagement element, and the power generation assembly is electrically connected with the second power storage device; and

and the processing element is arranged at one side of the first electricity storage device and is in information connection with the power element, the first electricity storage device and the second electricity storage device, so that the charging and discharging actions of the first electricity storage device and the second electricity storage device are controlled, and the driving effect of the power element is achieved.

The power generation device, wherein: the processing element is connected with a control piece, and the control piece is connected with the processing element in an information mode.

The power generation device, wherein: the main rotating part is a driving wheel of a vehicle body, and the driven rotating part is a driven wheel of the vehicle body.

The power generation device, wherein: the passive rotating piece is arranged at the outer side of the outer ring piece so as to drive the outer ring piece to rotate.

The power generation device, wherein: the power generation assembly is provided with a plurality of power generation coils connected to the rotating shaft of the driven wheel and a plurality of magnetic elements connected with the inner engaging element and surrounding the outer sides of the plurality of power generation coils.

The power generation device, wherein: the inner engaging element is provided with an engaging part and an extending part connected with the engaging part, and the plurality of magnetic elements are arranged on the extending part and extend to one side of the plurality of generating coils through the extending part.

The power generation device, wherein: the plurality of external engagement members have a plurality of right external engagement members engaged with the outer ring member and a plurality of left external engagement members connected to the plurality of right external engagement members, respectively.

The power generation device, wherein: the input current of the power storage device is 200 to 2000 amperes.

The power generation device, wherein: the capacity of the complex capacitor is 1 farad to 5 farads.

The power generation device, wherein: the rotation effect of the passive rotating part is accelerated by the power amplification component and then transmitted to the power generation component.

By means of the structure, the processing element can control the first power storage device to lead the power supply into the power element, so that the power element drives the main rotating piece to rotate, and the main rotating piece can drive the driven rotating piece to rotate when rotating. When the driven rotating piece rotates, the outer ring piece can be driven to rotate, the outer ring piece can drive each outer meshing piece to rotate, the inner meshing pieces meshed with the outer meshing pieces are driven to rotate, and the rotating effect of the driven rotating piece is enhanced through the mode.

When the internal engaging element rotates, the generating component is driven to generate electric energy, the generated electric energy is guided into the second electricity storage device, when the current enters the second electricity storage device to carry out charging action, the current firstly passes through the reverse protection circuit substrate, the current flow direction is controlled by the reverse protection circuit substrate to avoid the generation of reverse current at the input end and the output end, then the current flows to the overload protection circuit substrate to stabilize the current and prevent overload, so that the electricity storage device can be charged by large current to achieve the aim of quick charging, and the electricity storage device can be discharged at the same time.

So just so can be quick be full of the power in the second electric storage device to because the rotatory effect of driven rotation piece can strengthen enlargiing through power amplification assembly, consequently can have stronger power generation effect, and then reach better power availability factor.

By means of the technology, the problem of poor power supply use efficiency can be broken through, and the practical progress of the advantages is achieved.

Drawings

Fig. 1 is a perspective view of a preferred embodiment of the present invention.

Fig. 2 is an exploded view of the interior of the front wheel in accordance with the preferred embodiment of the present invention.

Fig. 3 is a schematic view (a) of the inside of the front wheel according to the preferred embodiment of the present invention.

Fig. 4 is a right internal view of the front wheel according to the preferred embodiment of the present invention (ii).

Fig. 5 is a left inner schematic view (iii) of the front wheel according to the preferred embodiment of the present invention.

Fig. 6 is a schematic block diagram of the preferred embodiment of the present invention.

Fig. 7 is a rotation diagram (one) of the preferred embodiment of the present invention.

Fig. 8 is a rotation diagram (ii) of the preferred embodiment of the present invention.

Fig. 9 is a rotation diagram (iii) of the preferred embodiment of the present invention.

Fig. 10 is a schematic diagram of the starting current of the preferred embodiment of the present invention.

Fig. 11 is a schematic diagram of the charging current according to the preferred embodiment of the present invention.

Description of reference numerals: a power element 1; a main rotating member 2; a passive rotating member 3; a first electric storage device 4; a second electric storage device 5; a reverse protection circuit board 51; an overload protection circuit substrate 52; the electrical storage device 53; a capacitor 531; a power amplification assembly 6; an outer ring member 61; an outer engagement member 62; the left external engagement member 62 a; a right external engagement member 62 b; an inner engagement member 63; the engaging portion 631; an extension 632; a power generation module 7; a power generation coil 71; a magnetic element 72; a processing element 8; the control 81.

Detailed Description

To achieve the above objects and advantages, the preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Please refer to fig. 1 to 6, which are schematic diagrams illustrating a perspective view to a structural block according to a preferred embodiment of the present invention, and it can be clearly seen from the drawings that the present invention includes:

a power element 1, in the embodiment, the power element 1 is a motor disposed on an electric vehicle;

a main rotation member 2 provided at one side of the power element 1 and connected to the power element 1;

a driven rotation member 3 disposed at one side of the main rotation member 2, in this embodiment, the main rotation member 2 is a driving wheel of the electric vehicle, and the driven rotation member 3 is a driven wheel of the electric vehicle;

a first electricity storage device 4 disposed at one side of the power element 1 and electrically connected to the power element 1, wherein the first electricity storage device 4 in this embodiment is a battery disposed in the electric vehicle;

a second electricity storage device 5 disposed at one side of the power element 1 and electrically connected to the power element 1 and the first electricity storage device 4, wherein the second electricity storage device 5 comprises a plurality of reverse protection circuit boards 51, a plurality of overload protection circuit boards 52 electrically connected to the reverse protection circuit boards 51, and an electricity storage device 53 electrically connected to the overload protection circuit boards 52, wherein the electricity storage device 53 has a plurality of capacitors 531 connected in series;

a power amplifying assembly 6 connected to the driven rotating member 3, the power amplifying assembly 6 includes an outer ring member 61, a plurality of outer engaging members 62 disposed inside the outer ring member 61 and engaged with the outer ring member 61, and an inner engaging member 63 disposed at the center of the outer ring member 61 and engaged with each other respectively at each outer engaging member 62, wherein the outer ring member 61 is driven by the driven rotating member 3 to rotate, in the embodiment, the driven rotating member 3 is disposed at the outer side of the outer ring member 61 to drive the outer ring member 61 to rotate, the outer engaging members 62 and the inner engaging members 63 are gears engaged with each other, and as shown in fig. 3 to 5, the outer engaging member 62 has a plurality of left outer engaging members 62a and a plurality of right outer engaging members 62b connected to the left outer engaging member 62a, and the left outer engaging members 62a are engaged with the outer ring member 61 to rotate by the driving effect of the outer ring member 61, when the left external meshing piece 62a rotates, the corresponding right external meshing piece 62b is driven to rotate, and the right external meshing piece 62b is connected with the internal meshing piece 63, so that the internal meshing piece 63 is driven to rotate;

a power generation unit 7 provided at one side of the power amplification unit 6, the power generation unit 7 having a plurality of power generation coils 71 connected to a rotation shaft of a driven wheel (driven rotor 3), and a plurality of magnetic elements 72 connected to the inner engaging member 63 and surrounding the outside of each power generation coil 71, and the inner engaging member 63 having a meshing portion 631 and an extended portion 632 connected to the meshing portion 631, each magnetic element 72 being provided on the extended portion 632 so as to extend to the outside of the power generation coil 71 via the extended portion 632;

a processing element 8 disposed at one side of the first electricity storage device 4 and connected to the power element 1, the first electricity storage device 4, and the second electricity storage device 5, wherein the processing element 8 in this embodiment is a circuit board in an electric vehicle as an example; and

an operating member 81 is connected to the processing element 8, and the operating member 81 of the present embodiment is exemplified by a throttle of an electric vehicle.

The structure of the present invention can be understood from the above description, and the power supply can achieve the advantage of better utilization efficiency according to the corresponding cooperation of the structure, and the detailed description will be described below.

Please refer to fig. 1 to fig. 11, which are a perspective view and a schematic diagram of a charging current according to a preferred embodiment of the present invention, when the above components are used, it can be seen clearly from the figure that a user can transmit an actuating signal to the processing element 8 by rotating the operation member 81, the processing element 8 will guide the power source in the first power storage device 4 into the power element 1, so that the power element 1 drives the main rotating member 2 to rotate, thereby driving the electric vehicle to move, and the electric vehicle will drive the driven rotating member 3 to rotate when moving.

When the driven rotation member 3 rotates, as shown in fig. 7 to 9, the driven rotation member 3 drives the outer ring member 61 to rotate, the outer ring member 61 drives the left outer engaging member 62a of the outer engaging member 62 to rotate, the left outer engaging member 62a drives the right outer engaging member 62b to rotate, and the engaging portion 631 of the inner engaging member 63 is engaged with the right outer engaging member 62b, so that the inner engaging member 63 is driven to rotate by the right outer engaging member 62 b. Since each magnetic element 72 is located at the outer side of each power generation coil 71 by the extension effect of the extension portion 632, when the inner engaging member 63 rotates, each magnetic element 72 is driven to rotate outside each power generation coil 71, and then electrons inside each power generation coil 71 are driven to move by magnetic force, thereby generating current to enter the second power storage device 5.

When the current enters the second power storage device 5, the current is input from the input terminal of the reverse protection circuit substrate 51, and when the current is charged with the input current approaching the maximum charge capacity, the charging can be theoretically completed in about one second, but in the charging process, when the battery capacity approaches the full load, the input of the current must have a buffer, so that the overall charging speed is about three seconds. Since the electric storage device 53 has a plurality of capacitors 531 connected in series, and the capacity of each capacitor 531 is 1 farad (F) to 5 farad (F), that is, the electric storage device 53 stores electric energy of 200 amperes (a) to 2000 amperes (a), the input current of the electric storage device 53 can be 200 amperes (a) to 2000 amperes (a). And the charging time varies with the difference between the magnitude of the input current and the maximum amount of charge of the accumulator 53, so the required charging time is about 3 seconds to 3 minutes. The charging efficiency of the second power storage device 5 can be achieved by relying on the reverse protection circuit board 51 and the overload protection circuit board 52, the reverse protection circuit board 51 functions to control the current flow to avoid the input end and the output end from generating reverse current, and the overload protection circuit board 52 functions to reduce the current output speed to stabilize the current and prevent overload. When the amount of charge passing through a certain section of the conductive line per unit time is greater than a certain value, an unstable state is easily generated, and the floating rate of the instantaneous current amount is increased, so that the overload condition of the electric device occurs, and the plurality of overload protection circuit substrates 52 solve the problem, so that even if a high current is passed through the input end, the problems of overload and the like do not occur to the whole structure, and the problem of overheating does not occur because the charging time is extremely short. In addition, when the power storage device 53 is discharging, the reverse protection circuit board 51 is additionally required to ensure that the currents of the input terminal and the output terminal are in and out simultaneously, so that the problem of reverse current is avoided, and the overload protection circuit board 52 has the effect of reducing the current output speed, so that even if the power storage device 53 has a large power storage capacity, no redundant power consumption is caused, and the service life of the power storage device 53 can be prolonged.

By means of the above functions, the second power storage device 5 can have the effect of a super capacitor, so as to achieve the advantage of fast charging and slow discharging, which means that the power of the power generation assembly 7 can be fast replenished into the second power storage device 5, and when the power generation assembly 7 starts to supply power to the second power storage device 5, the processing element 8 can control the second power storage device 5 to supply power to the power element 1, so that the power element 1 can continuously operate, and because of the effect of the super capacitor, no load condition is generated when the power is transmitted, so that the power element 1 can be more stable when being started, and because the second power storage device 5 has the characteristic of fast charging and slow discharging, the power supplied by the power generation assembly 7 can be fast charged, and the time for outputting the power is prolonged, so as to enhance the use efficiency of the power.

Further, the power generation efficiency of the power generation module 7 is proportional to the rotational speed of the magnetic member 72, i.e., the faster the inner engaging member 63 provided with the magnetic member 72 rotates, the higher the power generation efficiency. Because the inner engaging member 63 is driven to rotate by the outer engaging member 62 in a manner similar to a planetary gear in cooperation with the outer ring member 61, the rotation speed given by the driven rotation member 3 can be greatly increased, for example, by using a planetary gear with a gear ratio of 2 times (the ratio can be adjusted according to requirements, but is not limited), when the driven rotation member 3 rotates one circle, the inner engaging member 63 rotates two circles, so that the rotation efficiency is greatly increased, and the use efficiency of the power supply is improved.

The foregoing description is intended to be illustrative rather than limiting, and it will be appreciated by those skilled in the art that many modifications, variations or equivalents may be made without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (9)

1. A power generation device is characterized by mainly comprising:

a power element;

the main rotating piece is arranged at one side of the power element and is connected with the power element so as to drive the main rotating piece to act through the power element;

the driven rotating piece is arranged at one side of the main rotating piece and is connected with the main rotating piece so as to be driven to rotate by the action effect of the main rotating piece;

the first power storage device is arranged at one side of the power element and is electrically connected with the power element;

the second electricity storage device is arranged at one side of the power element and is electrically connected with the power element and the first electricity storage device, the second electricity storage device comprises a plurality of reverse protection circuit substrates, a plurality of overload protection circuit substrates and an electricity storage device, the plurality of overload protection circuit substrates are arranged at one side of the plurality of reverse protection circuit substrates and are respectively and electrically connected with the plurality of reverse protection circuit substrates, the electricity storage device is arranged at one side of the plurality of overload protection circuit substrates and is electrically connected with the plurality of overload protection circuit substrates, and the electricity storage device is internally provided with a plurality of capacitors which are mutually connected in series;

the power amplification assembly is connected with the driven rotating part and comprises an outer ring piece, a plurality of outer meshing pieces which are arranged in the outer ring piece and are meshed with the outer ring piece, and an inner meshing piece which is arranged at the center of the outer ring piece and is meshed with the outer meshing pieces respectively, wherein the outer ring piece is driven by the driven rotating part to rotate;

the power generation assembly is arranged at one side of the power amplification assembly and is connected with the internal engagement element so as to generate power through the rotation effect of the internal engagement element, and the power generation assembly is electrically connected with the second power storage device; and

and the processing element is arranged at one side of the first electricity storage device and is in information connection with the power element, the first electricity storage device and the second electricity storage device, so that the charging and discharging actions of the first electricity storage device and the second electricity storage device are controlled, and the driving effect of the power element is achieved.

2. The power generation apparatus of claim 1, wherein: the processing element is connected with a control piece, and the control piece is connected with the processing element in an information mode.

3. The power generation apparatus of claim 1, wherein: the main rotating part is a driving wheel of a vehicle body, and the driven rotating part is a driven wheel of the vehicle body.

4. A power plant according to claim 3, characterized in that: the passive rotating piece is arranged at the outer side of the outer ring piece so as to drive the outer ring piece to rotate.

5. The power generation apparatus of claim 4, wherein: the power generation assembly is provided with a plurality of power generation coils connected to the rotating shaft of the driven wheel and a plurality of magnetic elements connected with the inner engaging element and surrounding the outer sides of the plurality of power generation coils.

6. The power generation apparatus of claim 5, wherein: the inner engaging element is provided with an engaging part and an extending part connected with the engaging part, and the plurality of magnetic elements are arranged on the extending part and extend to one side of the plurality of generating coils through the extending part.

7. The power generation apparatus of claim 6, wherein: the plurality of external engagement members have a plurality of right external engagement members engaged with the outer ring member and a plurality of left external engagement members connected to the plurality of right external engagement members, respectively.

8. The power generation apparatus of claim 1, wherein: the input current of the power storage device is 200 to 2000 amperes.

9. The power generation apparatus of claim 1, wherein: the capacity of the complex capacitor is 1 farad to 5 farads.

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