TWI702779B - Impulse power generation system - Google Patents

Abstract

An impact type power generation system has two bases, an active component and a passive component. The top of each base is provided with a first bearing group and a second bearing group respectively, and the first shaft and the second shaft are respectively arranged on the axis; the active component The first rotating seat is provided with a plurality of radially extending first arm rods, and the second rotating seat of the passive component is provided with a plurality of radially extending second arm rods; the first shaft is provided with a first rotating seat parallel axis Connected to the power device, a second rotating seat is arranged on the second shaft and the power generating device is axially connected, the power device drives the first rotating seat to rotate, the first arm impacts the second arm, and the second rotating seat drives the power generating device to rotate, A small-sized power device converts potential energy into kinetic energy through the principle of rotational inertia and lever, and produces a structure that can drive high-power generators.

Description

Impulse power generation system

The invention relates to a power generation system, in particular to an impact power generation system that uses rotational inertia and the principle of leverage to convert potential energy into kinetic energy to drive the power generation device to operate and generate electricity.

Common fixed-point power generation devices mostly use solar energy, water power, wind power, or geothermal energy as power sources, but such power generated by natural kinetic energy is often limited by weather and terrain, and cannot stably generate the required power. Electricity, in addition, the power generation of a generator is proportional to the power, that is, the larger the power generation, the greater the power source required, and the aforementioned natural kinetic energy cannot drive the large-capacity generator set. Therefore, it can only do It is used as a small energy auxiliary power source.

Another common power generation device uses the alternate conversion of kinetic energy and potential energy to drive the generator. However, from the three laws of thermodynamics, it can be known that such power generation devices are actually limited by more unexpected factors and are more difficult to sustain. Power generation does not have complete commercial applications.

In view of the above-mentioned shortcomings of the conventional technology, the inventor researched and improved the above-mentioned shortcomings, and proposed a method of using a small power source to convert potential energy into kinetic energy and driving a large-capacity generator to generate electricity. Finally, the present invention is produced.

The main purpose of the present invention is to provide an impact-type power generation system that uses rotational inertia and lever principles to convert potential energy into kinetic energy to drive the power generation device to operate.

The secondary objective of the present invention is to provide an impact power generation system that amplifies a small power source based on the principle of rotational inertia and leverage to push a high-power power generation device.

In order to achieve the above-mentioned objectives and effects, the present invention is respectively connected with a power device and a power generating device. The technical means adopted include: two bases, an active component and a passive component, wherein: the base has a housing in the middle. Space, the top of each base is provided with a first bearing group and a second bearing group, a first shaft is provided between the first bearing group, a second shaft is provided between the second bearing group, and the first shaft The shaft is connected to the aforementioned power device, and the second shaft is axially connected to the aforementioned power generating device.

The active component has a first rotating seat arranged on the aforementioned first shaft, and the first rotating seat is provided with a plurality of first arms extending radially and welded to the first shaft.

The passive component has a second rotating seat arranged on the aforementioned second shaft, and the second rotating seat is provided with a plurality of second arms extending radially and welded to the second shaft.

The power device drives the first shaft to rotate in conjunction with the first rotating base. After the first arm rotates, it impacts the second arm to generate rotation, so that the second rotating base rotates in conjunction with the second shaft to drive the power generating device to rotate. In this way, a small power device can convert potential energy into kinetic energy through the principle of rotational inertia and leverage to produce a structure capable of driving a high-power generating device.

According to the above structure, the front end of the first arm has a first impact portion extending in an arc; and the front end of the second arm has a second impact portion, and there is a second impact portion between the second impact portion and the second arm. The angle difference causes the first impact part to hit the second impact part at the highest position, achieving a structure that maximizes potential energy conversion kinetic energy.

According to the above structure, the first impact part is provided with a plurality of first buffer members; and the aforementioned second impact part is provided with a plurality of second buffer members, so as to achieve a structure for reducing impact noise.

According to the above structure, the first impact portion is provided with a plurality of first magnetic elements; and the aforementioned second impact portion is provided with a plurality of second magnetic elements, so that when the first impact portion is close to the second impact portion, the first The magnetic element pushes the second magnetic element due to the mutual repulsion of the same magnetic poles, achieving a structure without impact noise during impact.

According to the above structure, the first rotating seat has a plurality of radially arranged first receiving grooves, and the first arm rods are respectively arranged in the first receiving grooves; and the aforementioned second rotating seat has a plurality of radially arranged first receiving grooves. The second receiving groove, the aforementioned second arm rods are respectively arranged in the second receiving groove.

According to the above structure, a positioning member for strengthening and fixing the first arm rod is provided in the first receiving groove.

According to the above structure, the power device includes, but is not limited to, an electric motor, an electric motor with a transmission mechanism, an internal combustion engine, a pneumatic motor, a waterwheel or a windmill.

In order to obtain a more detailed understanding of the above-mentioned purposes, effects and features of the present invention, the descriptions are as follows according to the drawings:

1: base

10: Containment space

11: The first bearing group

111: first shaft

12: The second bearing set

121: second shaft

2: Active component

21: The first rotating seat

211: First Containment Slot

22: First boom

221: First Impact

222: The first buffer

223: first magnetic element

23: positioning parts

24: first shell

241: Primary shaft hole

242: first positioning gap

3: Passive components

31: The second rotating seat

311: Second Containment Slot

32: second boom

321: Second Impact

322: second buffer

323: second magnetic element

34: second shell

341: second shaft hole

342: second positioning gap

35: second fixing element

4: power plant

41: fixed seat

42: Motor

43: drive mechanism

431: Driving Wheel

432: Passive Wheel

433: belt

5: Power generation device

[Figure 1] is a perspective view of a preferred embodiment of the present invention.

[Figure 2] is a perspective exploded view of a preferred embodiment of the present invention.

[Figure 3] is a top view of a preferred embodiment of the present invention.

[Figure 4] is a perspective view of another preferred embodiment of the present invention.

[Figure 5] is a perspective exploded view of another preferred embodiment of the present invention.

[Figure 6] is a schematic diagram of the action of another preferred embodiment of the present invention.

[Figure 7] is a perspective view of another preferred embodiment of the present invention.

[Figure 8] is an exploded perspective view of another preferred embodiment of the present invention.

[Figure 9] is a schematic diagram of the action of another preferred embodiment of the present invention.

Please refer to Figures 1 to 3, it can be seen that the present invention is connected with a power device 4 and a power generation device 5, which at least includes two bases 1, an active component 2 and a passive component 3, wherein: the two A accommodating space 10 is formed in the middle of the base 1. A first bearing set 11 and a second bearing set 12 are respectively arranged above each base 1. The first bearing set 11 can be provided with a first shaft 111 and a second bearing set. 12 can be axially provided with a second shaft 121, the first shaft 111 is connected with the aforementioned power unit 4, and the second shaft 121 is connected with the aforementioned power generating unit 5; in this embodiment, the power unit 4 is sandwiched by the fixing base 41 On the base 1, a motor 42 is correspondingly arranged on the base 1, and a driving mechanism 43 is provided between the motor 42 and the first shaft 111. In a preferred embodiment, the driving mechanism 43 has a shaft arranged at The driving wheel 431 of the motor 42 is shafted to the driven wheel 432 of the first shaft 111, and is driven by a belt 433 to link the driving wheel 431 and the driven wheel 432 to generate power; it should be noted that the above is only for the purpose of explaining the power The movement of the first shaft 111 driven by the device 4 does not limit the structural composition of the power device 4. Anything including but not limited to an electric motor, an electric motor with a variable speed mechanism, an internal combustion engine, a pneumatic motor, a watermill or a windmill shall be defined in the present invention Category.

The active assembly 2 has a first rotating seat 21 arranged on the aforementioned first shaft 111, and the inside is recessed into a plurality of radially arranged first receiving grooves 211, and they are respectively clamped and welded on the first shaft 111 A first arm 22 and a positioning member 23, and a plurality of first arm rods 22 and positioning members 23 extend radially, and a first impact portion 221 extending in an arc at the front end of the first arm 22; The middle section of the aforementioned first shaft 111 is formed by the first rotating seat 21 and correspondingly joined two first shells 24, so that the first shell 24 is penetrated by the two ends of the first shaft 111 through the first shaft hole 241 respectively. After setting, The two first housings 24 are combined with a plurality of first fixing elements 25, and the aforementioned first arm 22 and positioning member 23 are fixedly clamped on the first shaft 111 to form a stable and impact-resistant active impact member structure.

The passive component 3 has a second rotating seat 31 arranged on the aforementioned second shaft 121, and the inside is recessed into a plurality of radially arranged second receiving grooves 311, which are respectively clamped and welded to a second arm 32 , And the plurality of second arm bars 32 extend radially, each of the second arm bars 32 has a second impact portion 321 at the front end, and the second impact portion 321 and the second arm bar 32 are set at a bending angle difference, The angle difference is best to bend 15 to 45 degrees; the middle section of the second shaft 121 is formed by the second rotating seat 31 corresponding to the second housing 34, so that the two second housings 34 are respectively After the second shaft hole 341 is penetrated by the two ends of the second shaft 121, the two second housings 34 are combined with a plurality of second fixing elements 35, and the aforementioned second arm 32 is fixedly clamped on the second shaft 121 to form A stable and impact-resistant passive impacted part structure.

When acting, the aforementioned power unit 4 drives the first shaft 111 to rotate the first rotating base 21. The first arm 22 rotates and hits the second arm 32 clamped and welded by the aforementioned second rotating base 31. There is a bending angle difference between the second impact portion 321 and the second arm 32. Therefore, when the first impact portion 221 extending in an arc shape is impacted when the second impact portion 321 is at the highest position, the maximum potential energy is achieved. The kinetic energy is converted, and the aforementioned first impact portion 221 is formed in an arc-shaped extension structure, which enables the main and north moving parts to be quickly separated when impacted to avoid mutual interference, and the second rotating seat 31 is rotated and linked to the second shaft 121 to drive the power generating device. 5 Rotation, thereby achieving a small power device 4 through rotational inertia and lever principle, converting potential energy into kinetic energy, and generating a structure capable of driving the high-power generating device 5.

Please refer to FIGS. 4-6. Compared with the previous embodiments, another embodiment of the present invention is characterized in that: the first impact portion 221 is pivoted with a plurality of first buffer members 222, and the plurality of first buffer members 222 It can be a rubber wheel, or a material component such as a tire that can absorb impact noise; and, the second impact part 321 A plurality of second buffer members 322 are provided. The plurality of second buffer members 322 can be rubber wheels, tires that can absorb impact noise, and other material elements; when the first arm 22 rotates, it approaches the second arm 32, and After the first impact portion 221 hits the second impact portion 321, the first buffer member 222 and the second buffer member 322 can reduce the impact noise generated during the impact and achieve an equivalent functional structure.

Please refer to FIGS. 7-9. Compared with the previous embodiments, another embodiment of the present invention is characterized in that: the first impact portion 221 is provided with a plurality of first magnetic elements 223; and the second impact portion 321 is provided with A plurality of second magnetic elements 323, and the corresponding surfaces of the first magnetic element 223 and the second magnetic element 323 have the same magnetic poles. When the first arm 22 rotates, it approaches the second arm 32, and the first impact part 221 is close to When the second impact part 321 is used, the first magnetic element 223 can generate magnetic thrust to push the second magnetic element 323 by the way that the first magnetic element 223 mutually repels the magnetic poles, so that the second arm 32 drives the second rotation to rotate, thereby achieving the equivalent The structure is flexible and has no impact noise.

Based on the above, the impulse power generation system of the present invention can indeed be achieved as a novel and progressive invention. Yan applied for an invention patent in accordance with the law; however, the above description is only a description of the preferred embodiments of the present invention. All the changes, modifications, alterations or equivalent substitutions extended according to the technical means and scope of the present invention shall also fall within the scope of the patent application of the present invention.

1: base

11: The first bearing group

111: first shaft

12: The second bearing set

121: second shaft

2: Active component

21: The first rotating seat

211: First Containment Slot

22: First boom

221: First Impact

23: positioning parts

24: first shell

241: Primary shaft hole

25: The first fixing element

3: Passive components

31: The second rotating seat

311: Second Containment Slot

32: second boom

321: Second Impact

34: second shell

341: second shaft hole

35: second fixing element

4: power plant

41: fixed seat

42: Motor

43: drive mechanism

431: Driving Wheel

432: Passive Wheel

433: belt

Claims (6)

An impulse power generation system, which is respectively connected with a power device and a power generation device, which includes at least two bases with an accommodation space in between, and a first bearing set and a second bearing set are respectively arranged above each base. A first shaft is arranged on the shaft between a bearing group, and a second shaft is arranged on the shaft between the second bearing group. The first shaft is connected to the aforementioned power device, and the second shaft is connected to the aforementioned power generating device; an active assembly having The first rotating seat is arranged on the aforementioned first shaft. The first rotating seat is provided with a plurality of radially extending first arms and welded to the first shaft. The front end of the first arm has an arc extending A first impact part; a passive component, with a second rotating seat set on the aforementioned second shaft, the second rotating seat is provided with a plurality of radially extending second arms and welded to the first shaft, The front end of the second arm has a second impact part, and there is an angle difference between the second impact part and the second arm; the aforementioned power device drives the aforementioned first shaft to rotate the aforementioned first rotating seat, and the aforementioned first arm rotates After impacting the aforementioned second arm rod to rotate, the first impact part impacts the second impact part at the highest position to achieve a structure that maximizes the potential energy conversion kinetic energy, and the second rotating base rotates in conjunction with the second shaft to drive the power generator to rotate In this way, a small power device can be converted into kinetic energy through rotational inertia and lever principle to produce a structure capable of driving high-power generators. The impact power generation system of claim 1, wherein the first impact part is provided with a plurality of first buffer members; and the second impact part is provided with a plurality of second buffer members to achieve a structure for reducing impact noise. The impact power generation system of claim 1, wherein the first impact part is provided with a plurality of first magnetic elements; and the second impact part is provided with a plurality of second magnetic elements, so that the first impact part When the striking part approaches the second striking part, the first magnetic element is made to push the second magnetic element due to the mutual repulsion of the same magnetic poles, so as to achieve a structure without impact noise during impact. The impact-type power generation system according to claim 1, wherein the first rotating seat has a plurality of first receiving slots arranged radially, and the first arm rods are respectively disposed in the first receiving slots; and, the second rotating seat The seat has a plurality of second receiving slots arranged radially, and the aforementioned second arm rods are respectively arranged in the second receiving slots. The impact power generation system according to claim 4, wherein a positioning member for strengthening and fixing the first arm rod is provided in the first receiving groove. The impulse power generation system according to claim 1, wherein the power device includes but is not limited to an electric motor, an electric motor with a speed change mechanism, an internal combustion engine, a pneumatic motor, a watermill or a windmill.

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