CN211422838U - Power plant - Google Patents

Abstract

The utility model relates to a power device, the main structure comprises a bearing body, a main rotating part pivoted on the bearing body, a first auxiliary rotating part movably arranged at the side of the main rotating part, a second auxiliary rotating part movably arranged at the other side of the main rotating part, a plurality of driving mechanisms connected with the first auxiliary rotating part or the second auxiliary rotating part, a power supply element arranged at the side of the bearing body, a first power generation mechanism arranged at the side of the first auxiliary rotating part, a second power generation mechanism arranged at the side of the second auxiliary rotating part, a plurality of power elements connected with the main rotating part, a plurality of connecting elements arranged between the main rotating part and the first auxiliary rotating part as well as the second auxiliary rotating part, thereby, the power element is used for driving the main rotating part to continuously rotate, the bearing weight and the gravity center of the main rotating part are always the same through the first auxiliary rotating part and the second auxiliary rotating part, and the power generation action is carried out through the rotating effect, so as to achieve the effects of saving energy and prolonging the service life.

Description

Power plant

Technical Field

The utility model provides a power device, in particular to a power device with the effects of energy conservation and prolonged service life.

Background

In industrialized countries, the development of energy resources is a prerequisite for technologies such as agriculture, transportation, garbage collection, information technology, communication and the like, and since the industrial revolution, the use of energy is increasing, and serious problems such as global warming have potential serious risks all over the world at present. Also, since economic activities such as manufacturing and transportation are intensive, problems of energy efficiency, dependence, safety, price, etc. are also of concern, energy resources in the context of human society, generally referred to as materials such as fuels, petroleum processing products and electricity, are available energy sources because they can be easily converted into other energy sources of a specific kind of use.

In nature, energy sources can take several different forms: heat, electricity, radiation, chemical energy, and the like. The forms can be converted into each other, such as by using a power generation device, so as to convert chemical energy into usable electric energy.

However, the power generation device has the following problems and disadvantages to be improved when in use:

the power generation efficiency is poor, the power generation capacity is poor, the time is short, and the energy consumption is large.

Therefore, how to solve the above-mentioned existing problems and deficiencies is solved by the present invention.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at: the main rotating part is matched with the first auxiliary rotating part and the second auxiliary rotating part to achieve the effects of saving energy and prolonging the service life.

To achieve the above object, the main structure of the present invention comprises: a supporting body, the pivot is equipped with a main rotation piece on the supporting body, the both sides punishment of main rotation piece do not parallel activity is provided with a first secondary rotation piece and a second secondary rotation piece, and the weight of first secondary rotation piece and second secondary rotation piece equals and is less than main rotation piece, first secondary rotation piece and second secondary rotation piece are connected with a plurality of drive mechanism, the side department of first secondary rotation piece still is equipped with a first power generation mechanism, the side department of second secondary rotation piece also is equipped with a second power generation mechanism, be connected with a plurality of power component and a plurality of connecting element on the main rotation piece, the side department of supporting body still is equipped with one respectively with first power generation mechanism, second power generation mechanism and power component electric connection's power supply element.

Through foretell structure, the user can be earlier through drive mechanism with first secondary rotation piece laminating on the main rotation piece, the second secondary rotation piece drives simultaneously and keeps away from the main rotation piece, and with first secondary rotation piece and main rotation piece interconnect through connecting element, later power component can drive the main rotation piece through the electric energy that power supply element gave and start the rotation and actuate, and drive first secondary rotation piece through the main rotation piece and rotate and actuate, can let first secondary rotation piece and main rotation piece have the same rotational speed, when first secondary rotation piece accelerates to a predetermined speed, drive mechanism can drive first secondary rotation piece and leave the main rotation piece, and rotate the effect through first secondary rotation piece and cooperate first generating mechanism and carry out the electricity generation action, again with the electric energy benefit who sends fill in the power supply element.

When the first auxiliary rotating part leaves the main rotating part, the driving mechanism can drive the second auxiliary rotating part to be attached to the main rotating part, and the second auxiliary rotating part is connected with the main rotating part through the connecting element, so that the second auxiliary rotating part can rotate and actuate through the driving effect of the main rotating part, and the rotating speed of the second auxiliary rotating part also reaches a preset speed.

When the rotational speed of first secondary rotation piece reduces, can be through drive mechanism with first secondary rotation piece close to on the main rotation piece, with once more through connecting element with first secondary rotation piece connect on the main rotation piece, make first secondary rotation piece can get back to predetermined speed once more through the drive effect of main rotation piece, when first secondary rotation piece laminates on the main rotation piece once more, drive mechanism can drive the second secondary rotation piece promptly and leave the main rotation piece, the rotation effect of reuse second secondary rotation piece cooperates the second power generation mechanism and carries out the electricity generation action, and the second power generation mechanism also can be with in the leading-in power supply element of power, can utilize first power generation mechanism cooperation second power generation mechanism to continuously produce the effect of electricity generation, and because the produced electric power of first power generation mechanism and second power generation mechanism can lead-in the power supply element, so can increase of service life.

Because the first auxiliary rotating part and the second auxiliary rotating part have equal weight and are smaller than the main rotating part, when the main rotating part continuously rotates, no matter the first auxiliary rotating part or the second auxiliary rotating part is attached to the main rotating part, the influence on the energy generation required by the continuous rotation of the main rotating part is small, and because one of the first auxiliary rotating part or the second auxiliary rotating part is connected with the main rotating part at any time, the weight and the gravity center of the main rotating part during rotation can be always kept the same, so that the main rotating part can rotate more stably, and when the main rotating part can rotate stably, the energy required by the main rotating part to continuously keep rotation is relatively small by the power element, so that the energy-saving effect can be achieved.

Through the technology, the problem of poor power generation efficiency of the existing power generation device can be broken through, and the practical progress of the advantages is achieved.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

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

Fig. 2 is an exploded view of the preferred embodiment of the present invention.

Fig. 3 is an exploded view of the preferred embodiment of the present invention.

Fig. 4 is a schematic block diagram of the preferred embodiment of the present invention.

Fig. 5 is a first driving diagram (i) according to the preferred embodiment of the present invention.

Fig. 6 is a first driving diagram (ii) according to the preferred embodiment of the present invention.

Fig. 7 is a schematic diagram (a) illustrating the movement of the preferred embodiment of the present invention.

Fig. 8 is a schematic diagram (ii) illustrating the movement of the preferred embodiment of the present invention.

Fig. 9 is a schematic diagram of power generation according to a preferred embodiment of the present invention.

Fig. 9A is an exploded view of another embodiment of the present invention.

Fig. 9B is a schematic view of the engagement according to the preferred embodiment of the present invention.

Fig. 10 is a second driving diagram according to the preferred embodiment of the present invention.

Fig. 11 is a perspective view of another preferred embodiment of the present invention.

Fig. 12 is an exploded view of a further preferred embodiment of the present invention.

Fig. 13 is an exploded view of another preferred embodiment of the present invention.

Fig. 14 is a schematic view of another preferred embodiment of the present invention.

Fig. 15 is a schematic diagram of an alarm according to still another preferred embodiment of the present invention.

Fig. 16 is an exploded view of a further preferred embodiment of the present invention.

Fig. 17 is an exploded view of another preferred embodiment of the present invention.

Fig. 18 is a schematic rotation diagram of another preferred embodiment of the present invention.

Fig. 19 is a perspective view of another preferred embodiment of the present invention.

Fig. 20 is an exploded view of another preferred embodiment of the present invention.

Description of the reference numerals

Supporting body 1, 1a, 1c

11b of rotation axis

12c

Primary rotating member 2, 2a, 2b, 2c

21. connecting element

211 main fastening part

212. secondary engagement portion

22b main eccentric part

23c sliding engagement portion

3, 3a, 3b of a first secondary rotational member

31, 31a of a first generating mechanism

311, 311a first magnet

312, 312a first coil group

32b of the first set of eccentric elements

4, 4a, 4b of a second secondary rotary member

41, 41a of a second power generation mechanism

411, 411a of a second magnet

412, 412a

42b of the second pair of eccentric members

Driving mechanism 5, 5c

51

52. the second driving motor group

6. power element

61. activating power element

Continuous power element

Power supply element 7, 7a

8a monitoring device

81a camera device

82a water quantity sensing device

83a temperature sensing device

84a mobile electronic device

9 a.

Detailed Description

To achieve the above objects and advantages, the present invention provides a technical means and structure, which is illustrated in detail in the following for the purpose of fully understanding the preferred embodiments of the present invention.

Referring to fig. 1 to 4, there are shown a perspective view to a block diagram of the structure according to the preferred embodiment of the present invention, which can be clearly seen from the drawings that the present invention includes:

a carrier 1;

a main rotating member 2 pivotally mounted on the supporting body 1, in this embodiment, the main rotating member 2 is a rotating disc;

a first auxiliary rotating member 3 movably disposed on the supporting body 1 and pivoted to the side of the main rotating member 2 in parallel, and in this embodiment, the first auxiliary rotating member 3 is a metal turntable disposed above the main rotating member 2 and pivoted to the same shaft, but the mutual positional relationship is not limited;

a second auxiliary rotating part 4 movably arranged on the bearing body 1 and parallelly pivoted on the side of the main rotating part 2 departing from the first auxiliary rotating part 3, and in the embodiment, the second auxiliary rotating part 4 is a metal turntable which is positioned below the main rotating part 2 and pivoted on the same shaft, but the mutual position relationship is not limited;

a plurality of driving mechanisms 5 disposed on the supporting body 1, and in this embodiment, the driving mechanism 5 includes a first driving motor set 51 disposed at a side of the first secondary rotating member 3 and a second driving motor set 52 disposed at a side of the second secondary rotating member 4, and is connected to the first secondary rotating member 3 and the second secondary rotating member 4 to drive the first secondary rotating member 3 and the second secondary rotating member 4 to move vertically, so as to approach to or be away from the primary rotating member 2, in this embodiment, the driving mechanism 5 is exemplified by using a motor driving manner, but not limited thereto, and can also be driven by oil pressure, air pressure, or mechanical driving manner;

a first generating mechanism 31 disposed on the carrier 1 and located at the side of the first sub-rotor 3, in this embodiment, the first generating mechanism 31 includes a plurality of first magnets 311 connected to the first sub-rotor 3 and a first coil set 312 disposed at the side of the first sub-rotor 3 and corresponding to the first magnets 311;

a second power generating mechanism 41 disposed on the carrier 1 and located at the second secondary rotor 4 side, the second power generating mechanism 41 in this embodiment includes a plurality of second magnets 411 connected to the second secondary rotor 4 and a second coil group 412 disposed at the second secondary rotor 4 side and corresponding to the second magnets 411;

a plurality of power elements 6 connected to the main rotor 2, in the embodiment, the power elements 6 are motors capable of driving the main rotor 2 to rotate, and are connected to each other in a gear engagement manner, but not limited thereto, and the power elements 6 have at least one starting power element 61 connected to the main rotor 2 for starting rotation and at least one continuous power element 62 connected to the main rotor 2 for continuous rotation;

a plurality of connecting elements 21 respectively disposed between the main rotor 2 and the first and second sub-rotors 3 and 4, in this embodiment, the connecting elements 21 are electromagnets disposed on the main rotor 2, and the first and second sub-rotors 3 and 4 are both metal rotating discs, so that the first or second sub-rotors 3 and 4 can be directly connected by the magnetic attraction effect through the connecting elements 21, thereby allowing the first or second sub-rotors 3 and the main rotor 2 to perform synchronous rotation; and

a power supply element 7 disposed at the side of the supporting body 1 and electrically connected to the first power generating mechanism 31, the second power generating mechanism 41, the driving mechanism 5, and the power element 6, respectively, wherein the power supply element 7 is a battery capable of storing and discharging electricity.

The structure of the present technology can be understood from the above description, and the corresponding coordination of the structure can have the advantages of saving energy and prolonging the power generation time, and the detailed description will be described below.

Please refer to fig. 1 to fig. 10, which are schematic diagrams illustrating a perspective view to a second driving schematic diagram according to a preferred embodiment of the present invention, when the above components are combined, as can be seen clearly from the drawings, before the start, a user can first combine fig. 5 and fig. 6, first drive the first secondary rotation member 3 to be attached to the main rotation member 2 through the first driving motor set 51 of the driving mechanism 5, when the first secondary rotation member 3 is attached to the main rotation member 2, the connecting element 21 near the side of the first secondary rotation member 3 will turn on the power supply to connect the first secondary rotation member 3 to the main rotation member 2 through the magnetic attraction effect, and at the same time, the second driving motor set 52 of the driving mechanism 5 will drive the second secondary rotation member 4 to be away from the main rotation member 2.

Then, the power supply device 7 will conduct the power into the power device 6, and the power device 6 will drive the main rotation member 2 to rotate, in this embodiment, the main rotor 2 is driven to start rotating by the starting power element 61 with larger torsion in the power element 6, when the main rotor 2 rotates to a predetermined speed, the start power element 61 is turned off, the main rotation member 2 is driven by the continuous power element 62 with smaller torsion and less power consumption to rotate continuously at a predetermined speed, however, the driving manner of the power element 6 is not limited, and the main rotating member 2 can be connected to a plurality of sets of motors with the same torque force, and when starting, the main rotating part 2 is driven to rotate by using a plurality of groups of motors as the starting power element 61 at the same time, when the rotation speed reaches a predetermined speed, the rotation is switched to a mode that only one set of motors is used as the continuous power element 62 for driving rotation.

When the main rotor 2 is accelerated to a predetermined speed for rotation, because the first sub-rotor 3 is connected to the main rotor 2 through the connecting element 21 and is pivoted on the same axis with the main rotor 2, and thus is also driven by the main rotor 2 and rotates to the predetermined speed, as shown in fig. 7 to 9, at this time, the connecting element 21 cuts off the power supply to cut off the connection effect between the first sub-rotor 3 and the main rotor 2, and the first driving motor set 51 drives the first sub-rotor 3 away from the main rotor 2 and moves the first magnet 311 on the first sub-rotor 3 to the outer side of the first coil set 312, so as to drive the first magnet 311 to rotate at the outer side of the first coil set 312 through the rotation effect of the first sub-rotor 3, thereby utilizing the electromagnetic effect to enable the first coil set 312 to generate the power supply, when the first generating mechanism 31 generates the power supply, power is conducted to the power supply element 7, thereby extending the lifetime of the power supply element 7.

When the first driving motor set 51 drives the first secondary rotation member 3 away from the primary rotation member 2, the second driving motor set 52 at the other side can drive the second secondary rotation member 4 to be attached to the primary rotation member 2, when the second secondary rotation member 4 is attached to the primary rotation member 2, the connection element 21 adjacent to the second secondary rotation member 4 can be powered on, so as to attract the second secondary rotation member 4 to the primary rotation member 2 through the magnetic attraction effect, and at this time, because the primary rotation member 2 is still rotating at the predetermined speed, the second secondary rotation member 4 can also be driven to the predetermined speed to rotate through the driving effect of the primary rotation member 2.

In the present embodiment, the connection element 21 is connected by an electromagnet in cooperation with the first and second auxiliary rotating members 3 and 4 made of metal, but it is not limited thereto, and other connection methods can be used, such as using a permanent magnet as the connection element 21 or using a fastening mechanism for fastening connection, wherein if a fastening mechanism is used, a main fastening portion 211 is provided on the main rotating member 2 as shown in fig. 9A and 9B, and a secondary fastening portion 212 capable of fastening the main fastening portion 211 is provided on each of the first and second auxiliary rotating members 3 and 4, so that when the first or second auxiliary rotating member 3 or 4 is fastened to the main rotating member 2, the secondary fastening portion 212 is fastened to the main fastening portion 211, thereby fastening the first or second auxiliary rotating member 3 or 4 to the main rotating member 2, so that the first or second auxiliary rotating member 3 or 4 is driven by the main rotating member 2 to rotate synchronously, the primary engaging portion 211 and the secondary engaging portion 212 are exemplified by ratchet teeth which can be engaged with each other.

When the rotating speed of the first rotating secondary 3 is reduced to reduce the power generation efficiency, as shown in fig. 6 and 10, the driving mechanism 5 can drive the first rotating secondary 3 to be attached to the main rotating member 2 again and to be connected to the main rotating member 2 through the connecting element 21, and at the same time, can drive the second rotating secondary 4 to leave the main rotating member 2, and move the second magnet 411 on the second rotating secondary 4 to the outer side of the second coil assembly 412, so as to drive the second magnet 411 to rotate at the outer side of the second coil assembly 412 through the rotating effect of the second rotating secondary 4, so that the second coil assembly 412 generates a power source, and when the second coil assembly 412 generates a power source, the power source can also introduce the power into the power supply element 7.

Since the first rotating sub-assembly 3 is connected to the main rotating assembly 2 through the connecting element 21 again, it is driven to rotate at a predetermined speed again, if the rotating speed of the second rotating sub-assembly 4 is reduced, the second driving motor set 52 is attached to the main rotating assembly 2 again, and is connected to the main rotating assembly 2 again through the connecting element 21 to perform an acceleration operation, and meanwhile, the first rotating sub-assembly 3 is driven away from the main rotating assembly 2 again through the first driving motor set 51 to perform a power generation operation in cooperation with the first power generation mechanism 31, and the above operations are repeated, thereby continuously supplementing power to the power supply element 7.

Since the first and second auxiliary rotating members 3 and 4 have the same weight and the same weight is smaller than that of the main rotating member 2, when the main rotating member 2 rotates, one of the first and second auxiliary rotating members 3 and 4 is always connected to the main rotating member 2, so that the overall weight and the center of gravity of the main rotating member 2 can be maintained to be the same, and the rotating effect of the main rotating member 2 can be more stable, and therefore, the power required for continuously rotating the main rotating member 2 can be reduced, and since the weights of the first and second auxiliary rotating members 3 and 4 are smaller than that of the main rotating member 2, when the first and second auxiliary rotating members 3 and 4 increase the rotating speed through the main rotating member 2 to return to the predetermined speed, the consumed energy is relatively small, and thus the energy saving effect can be achieved, and the first and second power generating mechanisms 31 and 41 can guide the generated power to the power supply element 7 again, the power supply amount of the power supply element 7 can be increased to prolong the service time of the power device.

Referring to fig. 11 to 15, a perspective view to an alarm diagram of another preferred embodiment of the present invention is shown, and it can be clearly seen from the drawings that the present embodiment is different from the above embodiments in that the first auxiliary rotating element 3a and the second auxiliary rotating element 4a are respectively disposed on the left and right sides of the main rotating element 2a, thereby indicating that the position relationship is not limited.

In the present embodiment, the first coil group 312a of the first power generating mechanism 31a and the second coil group 412a of the second power generating mechanism 41a are respectively connected to the first rotating sub-assembly 3a and the second rotating sub-assembly 4a to be driven by the first rotating sub-assembly 3a and the second rotating sub-assembly 4a to move, and the first magnet 311a and the second magnet 411a are respectively disposed at the sides of the first coil group 312a and the second coil group 412a, thereby indicating that the types of the first power generating mechanism 31a and the second power generating mechanism 41a are not limited.

In this embodiment, a plurality of monitoring devices 8a and a lightning arrester 9a are disposed at the side of the supporting body 1a, and the monitoring devices 8a are a photographing device 81a, a water quantity sensing device 82a and a temperature sensing device 83a, respectively, but the number of the monitoring devices is not limited, and the lightning arrester 9a is a lightning rod disposed on the supporting body 1a, so as to achieve the effect of lightning protection and prevent short circuit caused by lightning strike.

The monitoring device 8a can be wirelessly connected to a mobile electronic device 84a (e.g., a mobile phone), so that a user can monitor or control the power device through the mobile electronic device 84a, and the supporting body 1a of the present embodiment is a transparent housing, so that the user can directly observe the internal action state, and when an abnormal condition (e.g., flooding or over-high temperature) occurs, the monitoring device can immediately report to the user through the mobile electronic device 84a, and stop the actuation of the power device (e.g., directly cut off the power supplied by the power supply element 7a, i.e., stop the actuation of the power device), thereby increasing the safety and convenience in use.

Referring to fig. 16 to 18, which are exploded (a) to rotated schematic views of another preferred embodiment of the present invention, it can be clearly seen that the present embodiment is substantially the same as the above embodiments, in the present embodiment, a main eccentric member 22b is disposed on the main rotating member 2b, the first sub-rotating part 3b and the second sub-rotating part 4b are respectively provided with a first sub-eccentric part 32b and a second sub-eccentric part 42b, in this embodiment, the main eccentric member 22b, the first sub-eccentric member 32b and the second sub-eccentric member 42b are weighted pieces having the same weight, the main rotor 2b, the first sub-rotor 3b, and the second sub-rotor 4b are rotated around the same rotation axis 11b, and the distances of the main eccentric member 22b, the first sub eccentric member 32b, and the second sub eccentric member 42b from the rotation axis 11b are equal.

When the first sub-rotor 3b or the second sub-rotor 4b is attached to the main rotor 2b, the first sub-eccentric 32b or the second sub-eccentric 42b and the main eccentric 22b are located at two sides of the rotation axis 11b, and fig. 18 shows a state that the first sub-eccentric 32b, the rotation axis 11b and the main eccentric 22b are in a straight line, so that no matter the first sub-rotor 3b or the second sub-rotor 4b is attached to the main rotor 2b, the center of gravity of the main rotor 2b can be always maintained at the same position by the first sub-eccentric 32b or the second sub-eccentric 42b cooperating with the main eccentric 22b, thereby the rotation effect of the main rotor 2b during rotation can be more stable and smooth, and the energy required for maintaining the rotation of the main rotor 2b can be reduced.

Referring to fig. 19 and 20, a perspective view and an exploded view of another preferred embodiment of the present invention are shown, and it can be clearly seen from the drawings that the present embodiment is different from the above embodiments in that the supporting body 1c is a frame body, the supporting body 1c has a supporting groove 12c, the main rotating member 2c has a sliding engaging portion 23c correspondingly disposed in the supporting groove 12c, and the main rotating member 2c can be directly disposed on the supporting groove 12c of the supporting body 1c through the sliding engaging portion 23c, thereby indicating that the supporting body 1c is not limited in shape, and in the present embodiment, the driving mechanism 5c can be respectively connected to a ceiling or a floor, and the connection relationship is not limited.

However, the above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, so that the simple modifications and equivalent structural changes made by the contents of the specification and drawings should be included in the scope of the present invention.

To sum up, the utility model discloses a power device lies in for improving prior art key:

first, since the first and second sub-rotors 3 and 4 have the same weight and are smaller than the main rotor 2, when the first sub-rotor 3 or the second sub-rotor 4 is engaged with the main rotor 2 and accelerated thereby, the kinetic energy consumed for keeping the main rotor 2 rotating is less affected, thereby achieving the advantage of energy saving.

Secondly, since one of the first sub-rotor 3 or the second sub-rotor 4 is attached to the main rotor 2 at any time, the weight and the center of gravity of the main rotor 2 during rotation are kept the same, thereby making the rotation of the main rotor 2 more stable.

Third, the first power generation means 31 and the second power generation means 41 introduce power into the feeding element 7 again, thereby extending the life of the feeding element 7.

Fourth, the monitoring device 8a increases the convenience in use.

Fifth, the main eccentric member 22b is used to cooperate with the first sub eccentric member 32b or the second sub eccentric member 42b to maintain the center of gravity of the main rotating member 2b during rotation, thereby making the main rotating member 2b more stable during rotation, and further reducing the energy consumption required during continuous rotation.

Claims (7)

1. A power plant, characterized in that it comprises:

a carrier;

a main rotating part which is pivoted on the bearing body;

the first auxiliary rotating part is pivoted at one side of the main rotating part in parallel, and the weight of the first auxiliary rotating part is less than that of the main rotating part;

the second auxiliary rotating part is pivoted to one side of the main rotating part, which is far away from the first auxiliary rotating part in parallel, and the weight of the second auxiliary rotating part is the same as that of the first auxiliary rotating part;

the driving mechanisms are arranged at the side of the bearing body, are respectively connected with the first auxiliary rotating part and the second auxiliary rotating part and are used for driving the first auxiliary rotating part and the second auxiliary rotating part to move;

the power supply element is arranged at one side of the bearing body;

the first power generation mechanism is arranged at one side of the first auxiliary rotating part and is electrically connected with the power supply element, and is used for matching the rotating effect of the first auxiliary rotating part to generate power and leading a power supply into the power supply element;

the second power generation mechanism is arranged at one side of the second auxiliary rotating part and is electrically connected with the power supply element so as to perform power generation action by matching the rotating effect of the second auxiliary rotating part and lead a power supply into the power supply element;

the power elements are connected with the main rotating part and electrically connected with the power supply element, and are used as power sources when the main rotating part starts to rotate and power sources when the main rotating part continuously rotates; and

a plurality of connecting element, these connecting element locate respectively this main rotation piece and this first vice rotation piece between and this main rotation piece and this second vice rotation piece between to when this first vice rotation piece and this second vice rotation piece drive and be close to this main rotation piece through these drive mechanism, be connected through these connecting element and this main rotation piece, so that make this first vice rotation piece and this second vice rotation piece rotate through the drive effect of this main rotation piece.

2. The power device as claimed in claim 1, wherein the power elements have at least one starting power element connected to the main rotating member and at least one continuing power element connected to the main rotating member.

3. The power device as claimed in claim 1, wherein at least one monitoring device is provided at a side of the carrier for sensing and controlling an operation state of the power device.

4. A power plant according to claim 3, characterised in that the monitoring device is adapted to be connected to a mobile electronic device.

5. A power plant according to claim 3, wherein the monitoring means is any one of a camera means, a water level sensing means or a temperature sensing means.

6. A power plant according to claim 1, characterized in that a lightning conductor is provided at the side of the carrier.

7. The power plant of claim 1 wherein said primary rotating member has a primary eccentric member thereon, and said first secondary rotating member has a first secondary eccentric member thereon corresponding to the position of said primary eccentric member, and said second secondary rotating member has a second secondary eccentric member thereon corresponding to the position of said primary eccentric member.

Images