TWM566437U - Energy-saving power generator device - Google Patents

Abstract

The present invention is an energy-saving generator set device comprising a base, a transmission assembly and a power generation assembly. The transmission assembly and the power generation assembly are all disposed on the base. The power generation assembly includes a coil plate, a plurality of coil windings, a conductor, and a majority of rotations. a rod and a plurality of rotating magnets, the coil plate is arranged on the base, the coil winding is arranged on the coil plate, the conductor is fixed on the transmission component, the rotating rod is inserted through the coil plate, the rotating magnet is mounted on the rotating rod and adjacent to the conductor and extends into the coil winding, The energy-saving generator set device is provided with a transmission component and a power generation component in the base, and the eddy current generated by the change of the magnetic flux of the conductor drives the rotating magnet to rotate, so that most of the coil windings generate an induced current to improve the power generation efficiency, and the structure of the conductor is simple. The weight of the generator with more complicated structure is reduced, and the suspension effect is enhanced.

Description

Energy-saving generator set

This creation is a genset device, especially an energy-saving genset device that uses a cold-second law to rotate a magnet to generate electricity.

At present, the conventional power generation device transmits the kinetic energy provided by the power supply source to the generator set by using the transmission component, and converts the kinetic energy into electric energy through the generator set. However, the kinetic energy provided by the power supply source will transmit kinetic energy to the generator set through the transmission component, and the kinetic energy will be lost due to the frictional resistance between the components in the transmission assembly, so that the kinetic energy of the external supply is difficult to be effectively converted into electric energy by the power generating device. . For a long time, power generation devices have problems in that the transmission mechanism is difficult to increase the power generation efficiency due to the energy consumption of the operation.

In order to overcome the problem of poor power generation performance of the conventional power generation device, the creator has created a magnetic drive power generation device, which mainly uses a plurality of magnetic modules respectively arranged in each of the vertical plates of the base frame. And installing a magnetic drive shaft through the plurality of magnetic modules, and connecting the generator set with the magnetic drive shaft, wherein the magnetic drive shaft is respectively subjected to magnetic force of the magnetic module by using a plurality of shaft magnets on the shaft The magnetic drive shaft can be vertically suspended and rotated without friction resistance, and the torque and the rotational speed of the magnetic drive shaft can be improved, and the generator set can reduce unnecessary kinetic energy loss and achieve better power generation efficiency.

However, if the weight of the generator set of the existing magnetic drive power generation device is too heavy, and the plurality of magnetic modules can provide magnetic force insufficient to overcome the weight of the generator set, the magnetic force provided by the plurality of magnetic modules cannot support the drive shaft. The effect of causing the magnetic suspension is not good. During the rotation of the transmission shaft, the transmission shaft increases the force of the bottom end of the transmission shaft and the base frame due to the weight of the generator set, and the bottom of the transmission shaft If the frictional resistance is generated at the end, the rotational speed of the transmission shaft is affected and weakened, which causes a problem of reduced power generation efficiency.

The main purpose of the present invention is to provide an energy-saving generator set device, thereby improving the weight of the generator set of the existing energy-saving power generation device, resulting in insufficient magnetic suspension, resulting in a problem of reducing power generation efficiency.

In order to achieve the foregoing, the present energy-saving genset apparatus comprises: a pedestal defining an upright central axis; a transmission assembly, the transmission component being disposed in the base and located on the central axis, the transmission The assembly includes a drive shaft and a drive set, the drive shaft is rotatably assembled in the base and the drive shaft is located on the central axis, and the drive assembly is disposed on the drive shaft; a power generation component, the power generation component Mounted in the base, the power generating assembly includes a coil plate, a plurality of coil bases, a plurality of coil windings, a conductor, a plurality of rotating rods, and a plurality of rotating magnets, wherein the coil plate is fixed to the base, a plurality of coils are arranged on the coil plate at intervals. The plurality of coil windings are disposed on the plurality of coil bases. The conductors are fixed on the drive shaft and located above the coil plate, and the plurality of rotating rods Rotating through the coil plate and surrounding the transmission shaft, and two sides of each rotating rod correspond to two coil bases, and the plurality of rotating magnets are mounted on the plurality of rotating rods and adjacent to the guide a plurality of rotating magnets extend into the plurality of coil windings; a plurality of magnetic suspension modules, the plurality of magnetic suspension modules are assembled in the base and connected to the drive shaft, and each of the magnetic suspension modules includes a fixing plate, a shaft magnetic block and an inner magnetic ring group, the fixing plate is fixed in the base, and a tapered hole with a decreasing size from top to bottom is disposed in the center of the fixing plate, and the shaft magnetic block is fixed on the The transmission shaft is located in the tapered hole, and the inner magnetic ring is disposed on the hole wall of the tapered hole and has a gap between the magnetic block and the shaft magnetic block, and the magnetic force is formed between the inner magnetic ring group and the shaft magnetic block. The magnetic radial balance module is assembled in the base and connected to the drive shaft, and each magnetic radial balance module comprises a positioning plate and an inner magnetic block. An inner magnetic ring, the positioning plate is fixed on the base, the positioning plate is provided with a central through hole, the inner magnetic block is fixed on the transmission shaft and located in the through hole, and the inner magnetic ring is disposed in the through hole a hole wall of the hole and a gap with the inner magnetic block, the inner magnetic ring being the same as the inner magnetic block And a magnetic axial balance module, the magnetic axial balance module is mounted in the base and connected to the drive shaft, and the magnetic axial balance module comprises a plate and a fixed magnetic ring And adjusting the magnetic block, the seat plate is fixed in the base and forming a centrally disposed grouping hole, the reinforcing magnetic ring is disposed on the hole wall of the set of connecting holes, and the adjusting magnetic block is disposed on the driving shaft And above the magnetic flux ring, the adjusting magnetic block and the reinforcing magnetic ring have an axial gap by a magnetic repulsion force of the upper and lower sides.

The energy-saving genset device of the present invention is configured to rotate the conductor through the driving group by the driving assembly and the power generating component, and the magnetic flux originally transmitted by the magnetic force of the plurality of rotating magnets is rotated by the conductor. And a change occurs, the eddy current generated by the change of the magnetic flux of the conductor drives the rotation of the plurality of rotating magnets, and the plurality of coil windings generate an induced current during the rotation of the plurality of rotating magnets, thereby improving power generation efficiency and phase Compared with the complicated structure of the conventional generator set, the weight of the transmission component is relatively light, and the magnetic suspension module, the magnetic radial balance module and the magnetic axial balance module provide magnetic repulsive force and enhance The suspension effect also reduces the radial and axial sway and swing of the drive shaft at high speeds.

As shown in FIG. 1 , FIG. 3 and FIG. 4 , a preferred embodiment of the energy-saving generating set device of the present invention is disclosed. As shown in the figure, the energy-saving generating set device comprises a base 10 , a transmission component 20 , and a The power generating component 30, the plurality of magnetic suspension modules 40, the plurality of magnetic radial balancing modules 50, and a magnetic axial balancing module 60, the magnetic axial balancing module 60 can increase the number of uses according to actual use requirements.

As shown in FIG. 1 , FIG. 3 and FIG. 4 , the pedestal 10 defines a central axis 100 . In the embodiment, the pedestal 10 includes a top plate 11 , a bottom plate 12 , and a plurality of struts 13 . a plurality of first support frames 14 and a plurality of second support frames 15 , wherein the top plate 11 and the bottom plate 12 are vertically spaced apart, and the plurality of frame bars 13 are distributed and connected to the top plate 11 and the bottom plate 12 erectly, the plurality of A support frame 14 and the plurality of second support frames 15 are respectively arranged on the plurality of racks 13 at intervals.

As shown in FIG. 1 , FIG. 4 and FIG. 5 , the transmission assembly 20 is disposed in the base 10 and located on the central axis 100 . The transmission assembly 20 includes a transmission shaft 21 and a driving group 22A. The transmission shaft The driving group 22A is mounted on the driving shaft 21, wherein the driving group 22A is a motor unit. The driving unit 22A is mounted on the driving shaft 21, and the driving group 22A is a motor unit. The motor unit includes a rotor 221 and two stators 222. The rotor 221 is fixed on the transmission shaft 21, and the two stators 222 are fixed in the base frame and respectively located at upper and lower ends of the rotor 221, and the rotor 221 includes A flywheel body 223 and two permanent magnet magnet blocks 224 are respectively disposed at upper and lower ends of the flywheel body 223. The flywheel body 223 includes a flywheel upper portion 225 and a bottom surface formed on the flywheel upper portion 225. The flywheel lower portion 226 is a conical body with a decreasing top-down dimension. The flywheel lower portion 226 is a conical body with an increasing size from top to bottom. The upper portion 225 of the flywheel is symmetrical with the lower portion 226 of the flywheel, or 2, the drive group 22B is pneumatic In the embodiment of the unit, the wind turbine includes a turntable 227 and a plurality of blades 228. The turntable 227 is fixed to the drive shaft 21, and the plurality of blades 228 are spaced apart and disposed on the turntable 227.

As shown in FIG. 1 , FIG. 3 and FIG. 5 , the power generation assembly 30 is mounted in the base 10 and surrounds the transmission assembly 20 . In the embodiment disclosed in the drawings, the power generation assembly 30 surrounds the transmission assembly 20 . And located between the top plate 11 and the bottom plate 12. However, the position of the power generating component 30 disposed in the susceptor 10 is not limited to the position disclosed in the drawings.

The power generating component 30 is mounted in the base 10. The power generating component 30 includes a coil plate 31, a plurality of coil bases 32, a plurality of coil windings 33, a conductor 34, a plurality of rotating rods 35, and a plurality of rotating magnets 36A. The coil plate 31 is fixed to the base 10. The plurality of coil bases 32 are arranged on the coil plate 31 at intervals. The plurality of coil windings 33 are disposed on the plurality of coil bases 32. The conductor 34 is fixed. The rotating shaft 35 is disposed on the driving shaft 21 and located above the coil plate 31. The plurality of rotating rods 35 can rotate through the coil plate 31 and surround the transmission shaft 21, and two sides of each rotating rod 35 correspond to two coils. a plurality of rotating magnets 36A are mounted on the plurality of rotating rods 35 adjacent to the conductor 34. The plurality of rotating magnets 36A extend into the plurality of coil windings 33. The conductors 34 are aluminum blocks. Made of components.

As shown in FIG. 4 to FIG. 6, the magnetic poles of the rotating magnet 36A of the power generating assembly 30 are arranged adjacent to each other in a disk shape, and the magnetic poles on the rotating magnet 36A are odd pairs. In the embodiment disclosed in the drawings, The magnetic poles on the rotating magnet 36A are a pair, that is, one of the two magnetic poles (N, S), or as shown in FIG. 7, the magnetic poles on the rotating magnet 36B are three pairs, that is, two magnetic poles (N, S) three, or as shown in FIG. 8, the magnetic poles on the rotating magnet 36C are five pairs, that is, five magnetic poles (N, S), respectively, as shown in FIG. 5, FIG. 9 and FIG. The coil holder 32 has a coil groove 321 and a through hole 322. The coil groove 321 is a periphery of the coil holder 32. The through hole 322 extends through the center of the coil holder 32 and is located in the middle of the coil groove 321 . The coil winding 33 is located in the coil slot 321 . The rotating magnet 36 extends into the two through openings 322 of the two coil bases 32. Further, as shown in FIG. 3, the conductor 34 and the plurality of rotating magnets 36 exhibit a layer. In this aspect, the inventive energy-saving genset device can have a plurality of layers of the conductor 34 and the plurality of rotating magnets 36, presenting a plurality The conductor 34 is in the same manner as the plurality of rotating magnets 36.

As shown in FIG. 1 and FIG. 11 , the plurality of magnetic suspension modules 40 are mounted in the base 10 and connected to the transmission shaft 21 . In the embodiment disclosed in the drawings, the present invention discloses that the energy-saving generator set device has The two sets of magnetic suspension modules 40 are limited to two sets of magnetic suspension modules 40. One of the two sets of the magnetic suspension module 40 is disposed adjacent to the driving group 22A, and the other magnetic suspension module 40 is disposed adjacent to the bottom plate 12 of the base 10. position. The position of the magnetic suspension module 40 disposed in the base 10 is not limited to the position disclosed in the drawings. The plurality of magnetic suspension modules 40 are preferably disposed above and below the conductor 34.

As shown in FIG. 1 and FIG. 11 , each of the magnetic suspension modules 40 includes a fixed plate 41 , a shaft magnetic block 42 and an inner magnetic ring set 43 . The fixed plate 41 is fixed to the base of the base 10 . 13 is fixed in combination with the first support frame 14 , and a tapered hole 411 is formed in the center of the fixing plate 41 and is reduced in size from the top to the bottom. The shaft block 42 is fixed on the transmission shaft 21 and located in the tapered hole. 411, the inner magnetic ring set 43 is disposed on the hole wall of the tapered hole 411 and has a gap with the axial magnetic block 42. The inner magnetic ring set 43 and the axial magnetic block 42 form a magnetic force, wherein Each of the magnetic suspension modules 40 includes a magnetic ring set 44, a permanent magnet ring 45, and a connecting frame 46. A tapered ring groove 412 is formed in the fixing plate 41. The groove width of the tapered ring groove 412 is The magnetic ring set 44 is disposed in the tapered ring groove 412. The permanent magnet ring 45 is fixed to the transmission shaft 21 in conjunction with the connecting frame 46. The permanent magnet ring 45 is located on the fixed plate. In the tapered ring groove 412 of 41, the center of the permanent magnet ring 45 is located at the central axis 100, and the permanent magnet ring 45 is borrowed from the magnetic ring set 44. A gap is formed by the magnetic repulsion, and the drive shaft 21 is suspended in the base 10.

As shown in FIG. 1 and FIG. 11, the permanent magnet ring 45 of the magnetic suspension module 40 includes an upper magnetic pole segment 451 and a lower magnetic pole segment 452 located below the upper magnetic pole segment 451. The lower magnetic pole segment 452 is formed from top to bottom. a tapered tapered ring body, the upper magnetic pole segment 451 forms a tapered ring body with an increasing size from top to bottom, and the upper magnetic pole segment 451 and the lower magnetic pole segment 452 are symmetric with respect to the annular ridge line, and are mutually different magnetic polarities. Each of the magnetic ring groups 44 includes a first magnetic member 441 and a second magnetic member 442 disposed under the first magnetic member 441. The first magnetic member 441 and the second magnetic member 442 are disposed adjacent to each other in the upper and lower directions. In the ring groove 412, the two magnetic poles (N, S) of the first magnetic member 441 are arranged up and down, and the two magnetic poles (N, S) of the second magnetic member 442 are arranged radially inward and outward, and The magnetic pole segment 451 and the lower magnetic pole segment 452 of the permanent magnet ring 45 form a magnetic force with respect to the first magnetic member 441 and the second magnetic member 442 of the magnetic ring set 44, so that the transmission shaft 21 is suspended on the base 10 in.

As shown in FIGS. 1 and 11, the axial magnetic block 42 includes an upper magnetic pole portion 421 and a lower magnetic pole portion 422 located below the upper magnetic pole portion 421, and the lower magnetic pole portion 422 forms a tapered body which is reduced in size from top to bottom. The magnetic pole portion 421 is formed with a tapered body having an increasing size from top to bottom. The upper magnetic pole portion 421 and the lower magnetic pole portion 422 are joined to form an annular ridge line, and the upper magnetic pole portion 421 and the lower magnetic pole portion 422 are symmetric with respect to the annular ridge line, and are mutually The inner magnetic ring set 43 includes a first magnetic component 431 and a second magnetic component 432 disposed under the first magnetic component 431. The first magnetic component 431 and the second magnetic component 432 are adjacent to each other. Is disposed in the tapered hole 411, the two magnetic poles (N, S) of the first magnetic member 431 are arranged up and down, and the two magnetic poles (N, S) of the second magnetic member 432 are arranged radially inward and outward. The magnetic pole portion 421 and the lower magnetic pole portion 422 of the axial magnetic block 42 form a magnetic force with respect to the first magnetic member 431 and the second magnetic member 432 of the inner magnetic ring set 43 , and the transmission shaft 21 is suspended on the base. Auxiliary magnetic force is provided in the seat 10.

As shown in FIG. 1 and FIG. 12, the plurality of magnetic radial balancing modules 50 are mounted in the base 10 and connected to the transmission shaft 21, which reveals that the energy-saving generating unit of the present invention has five sets of magnetic radial balancing modes. Group 50, but not limited to five sets of magnetic radial balancing modules 50. The five sets of the magnetic suspension module 40 are respectively disposed between the top plate 11 of the base 10 and the driving group 22A, and between the driving group 22A and the magnetic suspension module 40 adjacent to the top plate 11 The magnetic suspension module 40 of the top plate 11 and the conductor 34, the conductor 34 and the magnetic suspension module 40 adjacent to the bottom plate 12, and the magnetic suspension module 40 adjacent to the bottom plate 12 and the bottom plate Between 12. The position where the magnetic radial balance module 50 is disposed in the base 10 is not limited to the position disclosed in the drawings.

As shown in FIG. 1 , FIG. 3 and FIG. 12 , each magnetic radial balance module 50 includes a positioning plate 51 , an inner magnetic block 52 and an inner magnetic ring 53 . The positioning plate 51 is a frame of the base 10 . The rod 13 is fixed together with the second support frame 15. The positioning plate 51 is provided with a central through hole 511 and a plurality of perforations 512 at the periphery. The inner magnetic block 52 is fixed on the transmission shaft 21 and located in the through hole 511. The inner magnetic ring 53 is disposed on the hole wall of the through hole 511 and has a gap with the inner magnetic block 52. The inner magnetic ring 53 and the inner magnetic block 52 have the same magnetic polarity, wherein each The magnetic radial balancing module 50 includes an annular magnetic group 54 , a magnetic ring 55 , and a bracket 56 . The positioning plate 51 defines an annular groove 513 , and the annular magnetic group 54 is disposed in the annular groove 513 . The magnetic ring 55 is fixed to the transmission shaft 21 in conjunction with the bracket 56. The magnetic ring 55 is located in the annular groove 513 of the positioning plate 51. The center of the magnetic ring 55 is located at the central axis 100, and the magnetic ring 55 and the ring magnetic A radial gap is formed between the sets 54 by a radial magnetic repulsive force relative to the central axis 100 to provide a balance between the rotation of the drive shaft 21, The two magnetic poles (N, S) of the annular magnetic group 54 are arranged vertically in the axial direction. The two magnetic poles (N, S) of the magnetic ring 55 are arranged vertically in the axial direction, and the two magnetic poles of the magnetic ring 55 and the toroidal magnetic The two magnetic poles of group 54 are opposite to the magnetic polarity to produce a radial magnetic repulsive force.

As shown in FIG. 1 and FIG. 13 , the magnetic axial balance module 60 is mounted in the base 10 and connected to the drive shaft 21 . In the embodiment disclosed in the drawings, the magnetic axial balance module 60 is located above the magnetic suspension module 40 positioned adjacent to the bottom plate 12. However, the position of the magnetic axial balance module 60 disposed in the base 10 is not limited to the position disclosed in the drawings.

As shown in FIG. 1 and FIG. 13 , the magnetic axial balance module 60 includes a plate 61 , a fixed magnetic ring 62 and an adjusting magnetic block 63 . The seat plate 61 is fixed in the base 10 and forms a The central connecting hole 611 and the plurality of outer through holes 612 are disposed on the hole wall of the set of connecting holes 611. The adjusting magnetic block 63 is disposed on the driving shaft 21 and located at the solid Above the magnetic ring 62, the adjusting magnetic block 63 and the fixed magnetic ring 62 have an axial gap by the magnetic repulsion of the upper and lower sides.

Further, as shown in FIG. 1 , FIG. 3 and FIG. 5 , the power generating component 30 includes a plurality of radial magnets 37 , a plurality of radial magnetic rings 371 , an axial magnetic ring 38 , and an axial magnet 381 . A radial magnet 37 is fixed on the plurality of rotating rods 35 and located in the through hole 512 of the positioning plate 51. The plurality of radial magnetic rings 371 are disposed on the hole wall of the through hole 512 of the positioning plate 51 and the plurality of holes There is a gap between the radial magnets 37. The plurality of radial magnetic rings 371 are opposite to the plurality of radial magnets 37. The axial magnetic ring 38 is located at the hole wall of the through hole 612. The axial magnet The 381 group is disposed on the rotating rod 35 and above the axial magnetic ring 38. The axial magnet 381 and the axial magnetic ring 38 have an axial gap by the relative magnetic repulsion of the upper and lower sides.

As shown in FIG. 1, FIG. 4 and FIG. 5, when the energy-saving generator assembly of the present invention is put into use, the drive group 22A is externally powered to cause the drive group 22A to rotate, and the drive shaft 21 is subjected to the drive group. The driving of the 22A is a motor group, and the driving force of the driving group 22A can be used to rotate the transmission shaft 21. Alternatively, as shown in FIG. 2, the driving group 22B is a wind power group, and the wind engine group receives the wind through the plurality of blades 228 to rotate the turntable 227, thereby driving the transmission shaft 21 to rotate.

As shown in FIG. 1 , FIG. 5 and FIG. 4 , the transmission shaft 21 counteracts the gravity by the magnetic force of the plurality of magnetic suspension modules 40 , so that the transmission shaft 21 can stand upright and hang in the base 10 to make the transmission. The shaft 21 and the conductor 34 are rotatable about the central axis 100 in the base 10. When the drive shaft 21 is operated to rotate the conductor 34, a magnetic force is generated around the rotating magnet 36A around the conductor 34. The conductor 34 rotates such that the magnetic flux on the conductor 34 constantly changes, and the conductor 34 generates an eddy current, and the eddy current causes the plurality of rotating magnets 36A around the conductor 34 to rotate, and the rotating magnet 36A rotates to cause a magnetic field change. The coil windings 33 on the two coil bases 32 on the rotating magnet 36A are induced to generate electric current, thereby achieving the purpose of power generation.

As shown in FIG. 1, FIG. 5 and FIG. 4, when the energy-saving genset device of the present invention is driven by the driving group 22A, the conductor 34 on the transmission shaft 21 is driven to rotate to generate an eddy current for the plurality of rotating magnets. The rotation of the 36A causes the two coil windings 33 to generate an induced current. The magnetic force of the plurality of magnetic suspension modules 40 offsets the gravity, so that the base 10 and the transmission shaft 21 are close to no friction loss, so that the transmission shaft The rotation of 21 can improve the rotational performance such as the torsion or the rotational speed, and the conductor 34 is rotated faster, thereby generating a larger eddy current to drive the plurality of rotating magnets 36A to rotate faster. The plurality of rotating magnets 36A The axial magnet 381 has a friction-free wear between the rotating rod 35 and the susceptor 10, and is more energy-saving. Moreover, during operation of the energy-saving genset device, a radial magnetic repulsive force is also provided to the propeller shaft 21 by a plurality of magnetic radial balancing modules 50, and a radial direction is provided to the rotating rod 35 through the plurality of radial magnets 36A. When the transmission shaft 21 and the plurality of rotating rods 35 are rotated at a high speed, the transmission shaft 21 and the plurality of rotating rods 35 can be effectively prevented from shifting left and right (radial), and the transmission shaft 21 and the plurality of the transmission shafts 21 can be effectively reduced. When the rotating lever 35 is oscillated, the smoothness of the transmission shaft 21 and the plurality of rotating levers 35 is improved.

In summary, the energy-saving genset device of the present invention has the eddy current generated by the change of the magnetic flux originally passing through the conductor 34 by the rotation of the conductor 34 by the transmission assembly 20 and the power generating assembly 30 in the susceptor 10. The plurality of rotating magnets 36A can be rotated to synchronously rotate a plurality of rotating magnets 36A to cause a plurality of coil windings 33 to generate an induced current, thereby improving power generation efficiency, and the transmission assembly 20 having a simple structure compared with the conventional conventional generator set The weight of the conductor 34 is relatively reduced, so that the magnetic suspension module 40, the magnetic radial balance module 50 and the magnetic axial balance module 60 provide a magnetic repulsion force, and the suspension effect is also reduced, and the transmission shaft 21 is rotated at a high speed. Shake and swing in the direction of the axis.

10‧‧‧ Pedestal
100‧‧‧ center axis
11‧‧‧ top board
12‧‧‧floor
13‧‧‧ pole
14‧‧‧First support frame
15‧‧‧Second support
20‧‧‧Transmission components
21‧‧‧ drive shaft
22A, 22B‧‧‧ drive group
221‧‧‧Rotor
222‧‧‧ Stator
223‧‧‧Flywheel body
224‧‧‧ permanent magnet block
225‧‧‧ flywheel upper
226‧‧‧Flywheel lower part
227‧‧‧ Turntable
228‧‧‧ leaves
30‧‧‧Power generation components
31‧‧‧ coil plate
32‧‧‧ coil holder
321‧‧‧ coil slot
322‧‧‧ wearing a mouth
33‧‧‧ coil winding
34‧‧‧Conductors
35‧‧‧Rotary rod
36A, 36B, 36C‧‧‧ rotating magnet
37‧‧‧ radial magnet
371‧‧‧radial magnetic ring
38‧‧‧Axial magnetic ring
381‧‧‧Axial magnet
40‧‧‧Magnetic suspension module
41‧‧‧ fixed plate
411‧‧‧Conical hole
412‧‧‧Conical ring groove
42‧‧‧Axis magnet block
421‧‧‧Upper magnetic pole
422‧‧‧low magnetic pole
43‧‧‧Inner magnetic ring set
431‧‧‧First magnetic component
432‧‧‧Second magnetic parts
44‧‧‧Magnetic ring set
441‧‧‧First magnetic member
442‧‧‧Second magnetic component
45‧‧‧Permanent magnet ring
451‧‧‧Upper pole segment
452‧‧‧low magnetic pole
46‧‧‧Connecting frame
50‧‧‧Magnetic radial balance module
51‧‧‧ Positioning board
511‧‧‧through hole
512‧‧‧Perforation
513‧‧‧ring groove
52‧‧‧ Inner magnetic block
53‧‧‧ Inner magnetic ring
54‧‧‧Circular magnetic group
55‧‧‧Magnetic ring
56‧‧‧ bracket
60‧‧‧Magnetic axial balance module
61‧‧‧ seat board
611‧‧‧ groups of holes
612‧‧‧Tongkong
62‧‧‧Solid magnetic ring
63‧‧‧Adjusting the magnetic block

Figure 1 is a side cross-sectional view of a preferred embodiment of the present invention. 2 is a side cross-sectional view of another preferred embodiment of the present invention. 3 is a side cross-sectional view of a power generating assembly of a preferred embodiment of the present invention. Figure 4 is a side cross-sectional view showing a conductor and a rotating magnet of a preferred embodiment of the present invention. Figure 5 is a top cross-sectional view of the rotating magnet of the conductor assembly and the power generating assembly of Figures 1 and 2; Fig. 6 is a top cross-sectional view showing a preferred embodiment of a rotating magnet of the present invention for creating an energy-saving generating unit. Fig. 7 is a top cross-sectional view showing another preferred embodiment of the rotating magnet of the present invention for creating an energy-saving generating unit. Figure 8 is a top cross-sectional view showing another preferred embodiment of the rotating magnet of the present invention. Figure 9 is a side elevational view of a coil former of a preferred embodiment of the present invention. Figure 10 is a front cross-sectional view showing a coil holder of a preferred embodiment of the present invention. Figure 11 is a side cross-sectional view showing a magnetic suspension module of a preferred embodiment of the present invention. Figure 12 is a side cross-sectional view showing the magnetic radial balance module of a preferred embodiment of the present invention. Figure 13 is a side cross-sectional view showing the magnetic axial balance module of a preferred embodiment of the present invention.

Claims (10)

An energy-saving genset apparatus comprising: a pedestal defining an upright central axis; a transmission assembly disposed in the base and located on the central axis, the transmission assembly including a drive shaft And a drive set, the drive shaft can be rotatably assembled in the base and the drive shaft is located on the central axis, the drive assembly is disposed on the drive shaft; a power generation component, the power generation component is mounted on the base In the socket, the power generating component comprises a coil plate, a plurality of coil bases, a plurality of coil windings, a conductor, a plurality of rotating rods and a plurality of rotating magnets, the coil plate is fixed on the base, and the plurality of coil seats are spaced apart Aligningly disposed on the coil plate, the plurality of coil windings are disposed on the plurality of coil bases, the conductor is fixed on the drive shaft and located above the coil plate, and the plurality of rotating rods can rotate through the a coil plate and surrounding the transmission shaft, and two sides of each rotating rod correspond to two coil bases, and the plurality of rotating magnets are mounted on the plurality of rotating rods and adjacent to the conductor, the plurality of rotating a magnet extends into the plurality of coil windings; a plurality of magnetic suspension modules, the plurality of magnetic suspension modules are assembled in the base and connected to the transmission shaft, and each of the magnetic suspension modules includes a fixed plate and an axis a magnetic block and an inner magnetic ring set, the fixing plate is fixed in the base, and a tapered hole with a decreasing size from top to bottom is disposed in the center of the fixing plate, and the shaft magnetic block is fixed on the transmission shaft and Located in the tapered hole, the inner magnetic ring is disposed on the hole wall of the tapered hole and has a gap with the axial magnetic block, and the inner magnetic ring group and the shaft magnetic block form a magnetic force; the plurality of magnetic paths The balance magnetic module is assembled in the base and connected to the transmission shaft, and each magnetic radial balance module comprises a positioning plate, an inner magnetic block and an inner magnetic ring. The positioning plate is fixed to the base, the positioning plate is provided with a centrally located through hole, the inner magnetic block is fixed on the transmission shaft and located in the through hole, and the inner magnetic ring is disposed on the hole wall of the through hole and a gap with the inner magnetic block, the inner magnetic ring and the inner magnetic block being of the same magnetic polarity; And a magnetic axial balance module, the magnetic axial balance module is mounted in the base and connected to the drive shaft, the magnetic axial balance module comprises a plate, a fixed magnetic ring and an adjustment magnetic a block, the seat plate is fixed in the base and defines a centrally located assembly hole, the fixed magnetic ring is disposed on the hole wall of the set of holes, and the adjusting magnetic block is disposed on the transmission shaft and located at the Above the magnetic flux ring, the adjusting magnetic block and the reinforcing magnetic ring have an axial gap by a magnetic repulsion force of the upper and lower sides. The energy-saving genset device of claim 1, wherein the positioning plate forms a plurality of perforations located at a periphery of the through hole, the seat plate forming a plurality of through holes at a periphery of the set of holes, the power generating component comprising a plurality of a radial magnet, a plurality of radial magnetic rings, an axial magnetic ring and an axial magnet, wherein the plurality of radial magnets are fixed on the rotating rod and located in the perforations of the positioning plate, the plurality of radial magnetic rings a hole is formed in the hole of the positioning plate and has a gap between the radial magnet and the radial magnet. The radial magnetic ring is opposite to the radial magnet. The axial magnetic ring is disposed on the hole wall of the through hole. The axial magnet is disposed on the rotating rod and located above the axial magnetic ring. The axial magnet and the axial magnetic ring have an axial gap by a magnetic repulsion force of the upper and lower sides, and the plurality of rotating magnets The two magnetic poles surround the rotating rod, and the magnetic poles on the rotating magnet are an odd pair, the coil base has a coil slot and a through hole, the coil slot is a periphery of the coil seat, and the through hole is penetrated through the The center of the coil holder is located in the middle of the coil slot, The coil winding is located in the coil slot. The energy-saving genset device of claim 1, wherein each of the magnetic radial balancing modules comprises a ring-shaped magnetic group, a magnetic ring and a bracket, wherein the positioning plate forms an annular groove, the annular magnetic group The magnetic ring is fixed to the transmission shaft in combination with the bracket, the magnetic ring is located in the annular groove of the positioning plate, the center of the magnetic ring is located at the central axis, and the magnetic ring and the ring magnetic A radial gap is formed between the groups by a radial magnetic repulsive force with respect to the central axis. The energy-saving genset device of claim 2, wherein each of the magnetic radial balancing modules comprises a ring-shaped magnetic group, a magnetic ring and a bracket, wherein the positioning plate forms an annular groove, the annular magnetic group The magnetic ring is fixed to the transmission shaft in combination with the bracket, the magnetic ring is located in the annular groove of the positioning plate, the center of the magnetic ring is located at the central axis, and the magnetic ring and the ring magnetic A radial gap is formed between the groups by a radial magnetic repulsive force with respect to the central axis. The energy-saving genset device of any one of claims 1 to 4, wherein each of the magnetic levitation modules comprises a magnetic ring set, a permanent magnet ring, and a connecting frame, and a cone is formed in the fixing plate. a ring groove, the groove width of the tapered ring groove is reduced from the top to the bottom, the magnetic ring set is disposed in the tapered ring groove, and the permanent magnet ring is fixed to the transmission shaft in conjunction with the connecting frame, a permanent magnet ring is located in the conical ring groove of the fixing plate, the center of the permanent magnet ring is located at the central axis, and a gap is formed between the permanent magnet ring and the magnetic ring group by magnetic repulsion, so that the transmission shaft is suspended in the In the pedestal. The energy-saving genset device of claim 5, wherein the permanent magnet ring of the magnetic suspension module comprises an upper magnetic pole segment and a lower magnetic pole segment below the upper magnetic pole segment, and the lower magnetic pole segment is reduced in size from top to bottom. The tapered ring body, the upper magnetic pole segment forms a tapered ring body with an increasing size from top to bottom, and the upper magnetic pole segment and the lower magnetic pole segment are symmetric with respect to the annular ridge line, and mutually different magnetic polarities, the magnetic ring group Each of the first magnetic member and the second magnetic member disposed under the first magnetic member, the first magnetic member and the second magnetic member are disposed adjacent to each other in the tapered ring groove, the first magnetic force The two magnetic poles of the member are arranged up and down, the two magnetic poles of the second magnetic member are arranged radially inward and outward, and the first magnetic pole of the magnetic pole segment and the lower magnetic pole segment of the permanent magnet ring with respect to the magnetic ring group The member and the second magnetic member form a magnetic force; the shaft magnet block includes an upper magnetic pole portion and a lower magnetic pole portion located below the upper magnetic pole portion, and the lower magnetic pole portion forms a tapered body with a decreasing size from top to bottom, and the upper magnetic pole portion is formed a tapered body having an increasing size from top to bottom, an annular ridge line is formed at an interface between the upper magnetic pole portion and the lower magnetic pole portion, and the upper magnetic pole portion and the lower magnetic pole portion are symmetric with respect to the annular ridge line, and mutually different magnetic polarities, the inner magnetic ring The set includes a first magnetic component and a second magnetic component disposed under the first magnetic component, and the first magnetic component and the second magnetic component are disposed adjacent to each other in the tapered hole, the first magnetic component The two magnetic poles are arranged one above the other, the two magnetic poles of the second magnetic component are arranged radially inward and outward, and the magnetic pole portion and the lower magnetic pole portion of the upper magnetic pole portion are opposite to the first magnetic component of the inner magnetic ring set, The second magnetic component forms a magnetic force. The energy-saving genset apparatus according to any one of claims 1 to 4, wherein the drive unit is a motor unit, the motor unit includes a rotor and two stators, and the rotor is fixed on the drive shaft. The two stators are respectively disposed in the base frame and are respectively located at the upper and lower ends of the rotor. The rotor includes a flywheel body and two permanent magnet magnetic blocks, and the two permanent magnet magnetic blocks are respectively disposed at upper and lower ends of the flywheel body. The flywheel body comprises a flywheel upper portion and a lower portion of a flywheel formed on an upper surface of the flywheel. The upper portion of the flywheel is a conical body with a decreasing size from top to bottom. The lower portion of the flywheel is a conical body with an increasing size from top to bottom. It forms a symmetry with the lower part of the flywheel. The energy-saving genset device of claim 5, wherein the drive group is a motor group, the motor group includes a rotor and two stators, the rotor is fixed on the drive shaft, and the two stators are fixed on The pedestal is located at the upper and lower ends of the rotor, and the rotor comprises a flywheel body and two permanent magnetic blocks, and the two permanent magnet blocks are respectively disposed at upper and lower ends of the flywheel body, and the flywheel body comprises a flywheel The upper portion and a lower portion of the flywheel formed on the bottom surface of the upper portion of the flywheel, the upper portion of the flywheel is a conical body with a decreasing size from top to bottom, and the lower portion of the flywheel is a conical body with an increasing size from top to bottom, and the upper portion of the flywheel is symmetrical with the lower portion of the flywheel. . The energy-saving genset device according to any one of claims 1 to 4, wherein the drive group is a wind power group, the wind engine group includes a turntable and a plurality of blades, and the turntable is fixed to the drive shaft Above, the plurality of blades are arranged at intervals and are disposed on the turntable. The energy-saving genset device of claim 5, wherein the driving group is a wind-driven group, the wind-driven group includes a turntable and a plurality of blades, and the turntable is fixed on the drive shaft, the plurality of blades Arranged at intervals and surrounding on the turntable.