TW201203806A - Drive system - Google Patents

Abstract

The creation provides a drive system, comprising a rack and a permanent magnet shield device. The permanent magnet shield device includes a first permanent magnet, a rotating shield module connected to periphery of the first permanent magnet, and a dynamic input module for driving the rotating shield module to rotate relative to the first permanent magnet; the rotating shield module sets at least one breach allowing threading of magnetic field line of the first permanent magnet; the drive system includes at least a moving member disposed actively relative to the rack, a drive control device for controlling the rotating shield module to rotate and at least a power output device outputting mechanical energy of the moving member; at least a second permanent magnet having identical polarity to that of the first permanent magnet respectively disposed on two sides of N pole and S pole of the first permanent magnet; one of the first permanent magnet and the second permanent magnet is disposed on the moving member while another one is disposed on the rack.

Description

201203806 々, invention description: [Technical field of invention] The present invention relates to a permanent magnet shielding device and an application system thereof, which can selectively cover a magnetic field line of a permanent magnet by rotating a shielding module to form a staggered change of a magnetic field At the same time, the permanent magnet shielding device can also perform energy conversion with other energy conversion devices to output energy. [Prior Art] Conventionally, the mechanical energy can be converted into electrical energy by the shielding device and the magnet, or the electrical energy can be converted into mechanical energy by the shielding device and the magnet, which has been commonly used in the technical fields of power generation systems, drive systems and the like. Among them, Chinese Utility Model Patent No. 00252880.0 discloses a high-induction synchronous capability permanent magnet synchronous motor on October 3, 2001, which includes a base and a stator assembled therein, and a rotating shaft, a core, and a permanent magnet. a rotor formed by a rod cage, wherein the radially distributed permanent magnets are embedded in the permanent magnet slots of the rotor core, and the permanent magnet slots are located below the rotor slots. There is a magnetic bridge between the two slots. However, there is no shielding sleeve inside the motor, and the shielding effect cannot be achieved, so that the integrated structure is not perfect; in order to solve the above problem, Chinese Patent Application No. 92114781.3 was disclosed on June 29, 1994, a magnetically conductive differential (transfer) magnetic force. a driving device comprising: a permanent strong magnet and a magnetic mover made of a permanent strong magnet, maintaining a certain gap between the stator and the magnetic pole, and providing a movable between the gaps Made of non-magnetic material

[SI 201203806 changes the intensity of the sheet-shaped magnetic differential (transfer) sub-magnetic field that changes the intensity of the magnetic lines between the two extremes, causing the magnetic mover to move away from or close to the stator. However, the patent's body structure is imperfect, lacking the necessary structure to achieve its function, and the loss in the process of energy conversion is large, and it is not suitable for the needs of industrial production. SUMMARY OF THE INVENTION The purpose of the present invention is to provide a drive system in which Wei is perfected and the loss of the conversion process is small, and the drive system uses a permanent magnet shielding device for energy conversion. In order to achieve the foregoing object, the technical solution of the present invention is: a driving button comprising: a frame and a permanent magnet shielding device, wherein the permanent magnet shielding device comprises a first permanent magnet; the connecting sleeve is disposed around the first permanent magnet Rotating the shielding module, the power input module, the power input module can drive the rotating shielding module to rotate relative to the first permanent magnet; and the rotating shielding module is provided with at least one magnetic field line for the first permanent magnet The aforementioned transfer system includes at least one moving member provided by the movable frame, a driving control device for controlling rotation of the rotating shielding module, and at least one outputting mechanical energy output device of the moving member; The first permanent magnet N pole and the S pole are each provided with at least one and the first permanent magnet polar phase_second permanent magnet; one of the first permanent magnet and the second permanent magnet is disposed on the moving member The other is disposed on the aforementioned rack. Further, the power output device includes a rotating shaft, and the rotating shaft is provided with a power output wheel. The rotating shaft is further provided with a flywheel. Further, the foregoing rotating shielding module includes a first and a second cover disposed in parallel with the pole faces of the first permanent magnet N pole face plate 8, and the first shielding member is spaced from the first permanent magnet N pole face and read The second lining is at the same distance from the axis of the first permanent magnet s

iSJ -4- 201203806 is 0.1 〜1 mm 〇 Further, the first permanent magnet is an axially magnetized disk-shaped permanent magnet, and the permanent magnet shielding device further includes a magnetic conductive mold mounted in the first permanent magnet. In the group, the magnetic conductive module is connected to the first permanent magnets N and S, and the rotating shielding module is magnetically connected to the magnetic conductive module. Further, the permanent magnet shielding device further includes an electromagnetic generating module controlled by the control device, and the magnetic lines generated by the electromagnetic generating module in the energized state can enter the rotating shielding module.

The magnetic pole of the electromagnetic generating module that generates a magnetic field in an energized state is in the same direction as the magnetic pole of the permanent magnet. The rotating shielding module comprises a first shielding member and a second shielding member, and the electromagnetic generating module cooperates with the aforesaid permanent mismatching side to magnetically saturate the distracting first-filament member. The electromagnetic generating module comprises an electromagnetic generating module for carrying a human input current, and the input current is an intermittent current. Further, the masking module includes a first shielding member and a second shielding member, and the thickness of the first shielding member and the second shielding member is between G 5 and 2 Gmm. The rotating shielding module comprises a first shielding member and a second shielding member, and the first shielding member and the second shielding member are formed by laminating a plurality of magnetic conductors. The rotating shielding module comprises a first rotating shielding module and a second rotating shielding module, and the front side first cover and the second second piece are connected to form a plurality of magnetic conductive paths. The surface and the flap and the paste are increased in diameter (4). The moving member is a linkage frame, and the linkage frame includes a first linkage m -5 - 201203806 rod and a second linkage rod, and the first aforementioned second permanent magnet . At least one of the linkage rod and the second water reading on the second moving rod and the second water reading on the second moving rod The second magnetic shielding device. The purpose of the present invention is as follows: 'The technical solution of the present invention can also be: a driving system, including -μ&. The device includes a first-permanent, a continuous and a hydro-magnetic shielding device, the foregoing The permanent magnet shielding group, the power input module is the above-mentioned ^=the first permanent magnet rotating in the rotating shielding mode around the first permanent magnet. The front module can drive the relative magnetic field line of the rotating shielding module. The '= mask module is provided with at least the first permanent magnet, and the (four) drive system further includes at least one movement scale corresponding to the aforementioned support raft activity, a drive (four) suction yoke energy efficiency and at least - Outputting the aforementioned moving parts, the mechanical magnetic city, the first wire, the permanent magnet, the 14th pole and the 8th pole, each having at least one guide =:::::: body and the aforementioned magnetic guide Zhao On the moving parts, the other force is to lose the lion, the fine transmission has the dynamic® fm _ 纟 帛 帛 Ν Ν 与 与The magnet N is a two-faced cymbal, a member, and a second shielding member. The first shielding member is spaced apart from the first permanent magnet by a distance of 0.1 to 1 mm from the first permanent magnet S. Reading [subtracting the body to the magnetized permanent touch, the aforementioned permanent magnet group penetrates the aforementioned magnetically permeable module mounted in the aforementioned first permanent magnet, and the magnetically permeable magnetic connection is connected to the N and S pole faces. Further, the rotating shielding module includes a first shielding member and a second shielding member, and the thickness of the first shielding member and the second shielding member are both 0.5. Further, the rotating shielding module comprises a first shielding member and a second shielding member, and the first shielding member and the second shielding member are formed by laminating a plurality of magnetic conductive bodies. The first rotating shielding module and the second rotating shielding module are connected to form a plurality of magnetic conductive paths. The first shielding member and the second shielding member are respectively connected with the permanent magnet N The pole face is arranged in parallel with the s pole face. Compared with the prior art, this book The advantages are: simple structure, perfect function, low consumption in energy conversion process, and high energy conversion efficiency. [Embodiment] Now, a specific embodiment of the present creation will be described in detail with reference to the drawings. First Embodiment and Power Generation Apparatus Constructed by the First Embodiment of the Permanent Magnet Screening Device: As shown in the first to third figures, the ring permanent magnet shielding device of the present embodiment includes a frame 11' in the frame A central fixed pumping 12 is fixed on the central fixed shaft 12, and the annular permanent magnet 13 is mounted on the central fixed shaft 12. The annular permanent magnet π is installed obliquely with the central fixed shaft π, and a rotating shielding mold is disposed outside the annular permanent magnet 13 The rotating shielding module 14 has a fan shape and the fan-shaped section of the rotating shielding module 14 is [shaped, and the fan-shaped surface angle is 180. (semicircular). The rotating shielding module 14 is mounted on the central fixing shaft 12 by the rotating connecting member 15. In this embodiment, two rotating connecting members 15 are disposed on the two sides of the rotating shielding module 14, respectively, and the rotating connecting member 15 is The two sides of the rotating shielding module 14 are fixedly connected, and each of the two rotating connecting members 15 is provided with a bearing 16 to realize the rotational connection between the rotating shielding module 14 and the central fixed shaft 12; there is a power input wheel 17 and In the present embodiment, the aforementioned power input wheel 17 is a pulley; in the embodiment, the ring-shaped permanent magnet 13 is axially magnetized, and the left portion of the ring-shaped permanent magnet 13 is set to N. The extreme right portion is the s pole, and the distance between the N pole surface of the annular permanent magnet 13 and the rotating shielding module 14 is equal to the distance between the S pole surface of the annular permanent magnet 13 and the rotating shielding module 14, and the distance value is usually 0.1. ~1 mm, preferably, 1 blood in this embodiment. The ring-shaped permanent magnet shielding device of the present embodiment can be applied to a power generating device. The design of the power generating device is: connecting the power input wheel 17 to a driving motor, and driving the motor to drive the shielding module 14 to rotate. The power generating coil 18 corresponding to the position of the wire-shaped permanent magnet 13 is mounted on the frame u. By rotating the shielding module 14, the magnetic field strength at the position of the power generating coil 18 can be continuously changed, so that a current can be generated in the power generating coil 18. . In this embodiment, the rotating connecting member 15 can position the rotating shielding module 14 to ensure that the distance between the annular permanent magnets 13 and the rotating shielding module 14 is equal, and the rotating shielding module 14 is smoothly rotated. The positioning problem of the rotating shielding module 14 on the central fixed shaft is solved by the wire in the rotating connecting member 15 _ two bearings, the rotating connecting member 15 is made of stainless steel and is not adsorbed by the permanent magnet Easy to install. In this embodiment, a rotating shielding module 14 is disposed outside the annular permanent magnet 13 to realize the rotation of the rotating shielding module 14 around the central fixed shaft 12. The rotating shielding module 14 and the annular permanent magnet 13 are created. The coaxial equidistant mounting has the characteristics of uniform force; when the rotating shielding module 14 rotates, it is not interfered by the annular permanent magnet 13, and only the power input wheel 17 inputs a small power, so that the rotating shielding module 14 can be realized. Turn. In this embodiment, the rotating magnetic shielding principle is used to continuously input a relatively small power by the power input wheel 17, which is used to drive the rotating shielding module 14 to continuously rotate, so that the magnetic flux changes, generates electric energy, and generates a power coil. 18 will output electrical energy. The aforementioned annular permanent magnet 13 in the present invention uses a permanent magnet made of ferrotitanium boron, and this kind of permanent 201203806 magnet has the advantage of making the drunk limit long energy consumption low. Referring to the fourth figure, the foregoing rotating shielding module 14 is composed of a plurality of layers of Shixia Steel #116 laminated, the thickness of which is between 0.5 and 15 mm, and the number of layers of Shixia steel is between 2 and 6 G. Department-(4) The coffin is wound into a multi-layered rectangular frame body' and then used to form a jade into the shape forming process. The rotating shielding module made of this material is light in weight, uniform in material, easy to take, and is shielded by rotation. The module utilizes the high magnetic permeability of the Shixia steel sheet and the large magnetic saturation. It is a magnetic field to establish a fast path of multiple magnetic lines of magnetic field, so that the magnetic lines of the N-pole to the S-pole of the ring-shaped permanent magnet form a magnetic circuit. The rotating shielding module 14 of the present embodiment is composed of a shielding body. Of course, the rotating shielding module 14 can also be composed of a plurality of shielding bodies 115. The plurality of shielding bodies ι 5 are axially disposed by the shielding bodies. The two rotary joints ls on the side are connected. As shown in the fifth figure, the aforementioned rotating shielding module can also have two fan-shaped surface angles of 9 inches. The shielding body, the two shielding body f-axis pairs are placed, and are connected by two rotating connecting members disposed on both sides of the shielding body. Of course, the coverage of the secret surface can be set by the actual security, such as %. 45 〇, 90. 60. 180. Wait.

Referring to the sixth embodiment, in order to improve the further embodiment of the present embodiment, the central fixed shaft casing is provided with a magnetic conductive sleeve 19 which is installed between the central fixed (four) disk annular hydromagnets η. That is, the magnetic conductive sleeve 19 is inserted through the N, st' of the annular permanent magnet 13 and the two ends of the magnetic conductive sleeve 19 are slidably connected to the rotating shielding sleeve 14 at both ends of the magnetic shielding sleeve. Corresponding contact faces 110. As shown in the seventh figure: 'With the design of the system, the magnetic flux 19 and the aforementioned rotating shielding 14 can be used to form magnetic conduction. When the rotating shielding 14 shields a part of the magnetic field of the annular permanent magnet 13, the second purchase of the bungee The magnetic field line 113 cannot penetrate the corresponding rotating shielding module wall 'only has to follow the magnetic conductive channel between the layers of the Shishi steel sheet in the rotating shielding module 14, and a part of the magnetic field line in the basin goes upwards and the surface is _ group ΜLeft 雠=The magnetic conductive loop formed in the upper part of the side wall leads back to the s pole of the magnetic field; among them, part of the magnetic field lines go downwards, and along the lower part of the left side of the rotating ship, the bottom of the rotating drum, the shape of the bottom wall ί S1 -9 - 201203806 The magnetic circuit leads back to the s pole of the magnetic field; it ensures that the magnetic circuit is smooth, reduces the rotational resistance of the rotating shielding module, and effectively increases the magnetic flux'. It improves the magnetic field utilization efficiency and reduces the magnetic field loss to increase the electric energy. Output power. The aforementioned magnetic conductive sleeve can be made of a magnetically permeable material such as a closed paste or a paste. As shown in the eighth and ninth drawings, in order to further improve the embodiment, the magnetic conductive sleeve 19 is jacketed with a spiral electromagnetic generating module 111, and the electromagnetic generating module 111 is mounted on the magnetic conductive sleeve. The cylinder 19 and the annular permanent magnet 13 are fixed by a positioning collar 112 mounted on both sides of the electromagnetic generating module hi. During the re-generation process, the aforementioned power generating coil 18 φ will generate an attractive force to the rotating shielding module 14 to hinder the rotation of the rotating shielding module 14; therefore, a current can be input to the electromagnetic generating module 111 to make the electromagnetic The generating module U1 generates a magnetic field in the same direction as the magnetic pole of the annular permanent magnet 13. Under the action of the current, the magnetic force line 114 introduced into the rotating shielding module 14 is instantaneously saturated and penetrates the rotating shielding module " A repulsive magnetic field of the same magnetic pole is formed between the 18 and the rotating shielding module 14, which can reduce the attraction force of a part of the power generating coil 18 to the rotating shielding module 14, and help to rotate the rotating motion of the shielding module 14. Preferably, the aforementioned input current is an intermittent current. The second embodiment of the permanent magnet shielding device and the power generating device constructed by the second embodiment of the permanent magnet shielding device: This embodiment is an improved technical solution based on the first embodiment of the permanent magnet shielding device, and the permanent magnet shielding device The same portions of an embodiment will not be described in detail. Referring to the tenth to twelfth drawings, the annular permanent magnet shielding device of the present embodiment has a frame 21 on which a center fixed shaft 22 is fixed, and the center fixed shaft 22 is mounted thereon. The annular permanent magnet 23 is installed in an interference manner with the central fixed shaft 22, and two rotating shielding modules 24 are disposed outside the annular permanent magnet 23; the rotating shielding module 24 is fan-shaped and rotates the shielding die. The fan-shaped section of the group 24 is [shaped, and the fan-shaped surface angle is 90. Each of the above-mentioned rotating shielding modules 24 is respectively mounted by the rotating connecting member 25 and the central fixing shaft 22; in this embodiment, four rotating connecting members 25 are provided, which are respectively disposed on two sides of the two rotating shielding modules 24; the aforementioned 201203806

The ring-shaped permanent magnet shielding device of the present embodiment can be applied to a power generating device, and the rotating connecting member 25 and the rotating shielding module are respectively provided with a bearing 26 in the rotating connecting member, which will not be described again; The frame 21 is mounted with a power generating coil 28 having the same principle as that of the first embodiment and no longer corresponding to the position of the permanent magnet 23. Similarly, the central fixing wire 22 is jacketed with a magnetically permeable sleeve 29 mounted between the central fixed shaft 22 and the annular permanent magnet 23, that is, the magnetic conductive sleeve penetrates the foregoing The N and s pole faces of the ring-shaped permanent magnet 23 are slidably connected to the rotating shielding module 24 at both ends of the magnetic shielding sleeve 29, and the two ends of the magnetic guiding sleeve 29 are provided with the contact of the rotating shielding module 24 The surface of the magnetic conductive sleeve 29 is provided with a spiral electromagnetic generating module, and the electromagnetic generating mold and the group are mounted on the magnetic conductive sleeve μ and the annular permanent magnet η 1, and are mounted on the electromagnetic generating mold. The positioning collar 212 on both sides of the group 211 is fixed. The two rotating shielding modules 24 in this embodiment are each composed of a shielding body. As shown in FIG. 13 , the rotating shielding module 24 can also be composed of a plurality of shielding bodies 213 , and a plurality of shielding bodies 213 . The shaft is symmetrically disposed, and is connected by a plurality of rotating connecting members 25 disposed on both sides of each shielding body 213. However, considering the practical application and the manufacturing cost, generally only a plurality of shielding bodies 213 and four rotating connecting members are generally used. 25 connected designs. The two rotating shielding modules 24 have an angle of 45 from four sectors. The shielding body 213 is composed and connected by four rotary connecting members 25 provided on both sides of each shielding body 213. The aforementioned fan sector angle can be set according to: -11- 201203806 The actual work needs to be set, for example 30. 45. 60. 90. Wait. The third embodiment of the permanent magnet shielding device and the power generating device constructed by the third embodiment of the permanent magnet shielding device: Referring to the fourteenth and fifteenth drawings, the disc-shaped permanent magnet thin-shell shielding device of the present invention is There is a frame 31 including a bottom plate, a left bracket plate 3U, and a right bracket plate 312. The support frame 34 is provided with a support member 34. The support member 34 includes a left half shaft 341, a cylindrical magnetic core 342, and a right half shaft 343. The cylindrical magnetic core 342 is provided with a disc-shaped permanent magnet.

33' The disc-shaped permanent magnet 33 is provided with a rotating shielding module 32; as shown in the sixteenth figure, the rotating shielding module 32 comprises two upper and lower symmetrical arrangements cut by a multi-layer silicon steel laminated blank. The butterfly end face body 323 is connected with a bridging side wall body 325 which is molded into a curved shape by using a multi-layer silicon steel sheet laminated blank. The bridging side wall body 325 assembles two butterfly end face bodies symmetrically arranged one above another by fastening joint parts, wherein The fastening connecting component is made of a magnetically permeable material, and the disc-shaped permanent magnet 33 comprises two circular end face magnetic poles, an outer cylinder surface and a central circular hole; the rotating shielding module 32 is rotated by the connecting member 32 322 by a bearing Mounted on the left and right half shafts 341, 343; the butterfly end face body is magnetically coupled to the cylindrical magnetic core body 342. In the present embodiment, a power input wheel 324 is mounted to the aforementioned rotary link 32. The power input wheel 324 can be powered by a drive belt and driven by a drive motor to drive the rotating module to 32 years old. The distance between the upper and lower end faces of the transfer mask module 32 and the two annular end face magnetic poles of the disc-shaped permanent magnet 33 is maintained at the outer cylindrical surface of the m-bridged sidewall body and the disc-shaped permanent magnet 33. The distance is kept at 2-5 mm. In the present embodiment, the supporting member 34 is composed of three segments and is composed of a middle segment column = a magnetic core 342, which is made of a magnetic conductive material (carbon steel material), and has good magnetic permeability, left. The left half of the segment made of a non-magnetic material (such as the alloy) is the right half shaft 343 made of a non-magnetic material; the left half shaft is corrected, the right half shaft 343 and the cylindrical magnetic core Μ 2 threaded connection 'support member 34 is fixed to the frame 31, and the cylindrical magnetic core 33 is fixedly mounted on the cylindrical magnetic core 342. The fixing method is a conventional technical means such as a spline connection. -12- 201203806 'The permanent magnet 33 is used to test the iron material, and the shape of the disc is composed of two circular end face magnetic poles, the outer cylindrical surface, the central circular hole and the permanent magnet are made by the magnetization process along the ^ direction (or the miscellaneous direction). The front ring magnets of the pre-magnet (4) are N-pole and s-pole, respectively. In the present embodiment, the aforementioned rotating shielding module has a multi-layered laminated ink structure, and the first two layers of the laminated laminated structure are continuous by the paste metal structure. Extended Wei thin sheet,

The thickness of the month P Shixi Steel >} is at 0.M 5, the number of layers of the paste is in the range of 4 to 9 layers, the two most preferred thickness systems, 3 coffees, and the most preferred layer number is 1 layer. ^ The specific production method = a rectangular length with a sufficient length _ steel thin plate using a mold to be wound into a multi-layer, using the cutting shape J1 art shouted into the shape as shown in the sixteenth figure - due to the molding work in the processing The process of rotating the shielding module 32 is not cut off as shown in FIG. The two butterfly-shaped end faces 326, 327' of the gantry are connected to the bridging of the butterfly end face body. The butterfly end face system is composed of two linings (4), which are arranged in a fan shape. 0 heart angle is 60. -90〇. Preferably, in this embodiment, a butterfly end surface having a central angle of 9 ^ is used. According to the actual use, the rotating shielding module 32 can also adopt an embodiment shown in the eighteenth embodiment. In the foregoing embodiment, the The rotating shielding module 32 adopts a material that is molded into a butterfly end face with curved edges and a fastening connection using a magnetic conductive material = together. The rotating mask and the middle and lower butterfly end faces 329 have a curved edge 33〇. The upper=face=333 belt, the edge 332; the upper and lower butterfly end faces are integrally formed by the other. m is = less magnetic leakage, reducing the weight of the rotating shielding module 32, and improving the magnetic shielding effect. The cylindrical magnetic core 342 is specially provided in the present invention, and the butterfly end face body milk is ensured from the structure. The magnetic 342 has a highly efficient magnetically conductive connection that leads through the N, S pole faces of the aforementioned annular permanent magnet. The magnetic conductive connection of the present embodiment means that the two end faces 323 of the ^-13-201203806 are optimally magnetically spaced from both end faces of the cylindrical magnetic core body sc during continuous rotation (generally G. G1-0. 1 mm), the butterfly end face body 323 and the 'touch 342 constitute a complete magnetic flux path. As shown in the nineteenth figure, the magnetic field line distribution of the disc-shaped permanent magnet 33 in the ^ state is as shown in the twentieth eye, and the cylindrical magnetic conductive 342 and the rotating shielding module 32 are added to the returning permanent %. The magnetic field lines are distributed. At this time, the magnetic lines of force are distributed along the two magnetic paths of the bridge (four) body and the cylindrical magnetic core of the rotating shielding module, and the force of the butterfly end face body is more uniform, thereby reducing the lion end face. The thickness of the body i of the present embodiment can be made in a power generation device, and the design cost of the power generation device is as shown in the fourteenth, fifteenth, and the left bracket of the aforementioned frame. A plurality of inductive power generating devices 35 are disposed on the right side of the plate 31, and the inductive power generating device 35 is disposed on both sides of the disc-shaped permanent magnets 33. The inductive power generating device used in the embodiment includes a conventional inductive iron core, an induction generating coil, and the like. Preferably, the inductive power generating device 35 is equipped with a wire loop. When the rotating mask module 32 is continuously rotated at a constant rotational speed, the magnetic field strength around the induction coil will be lightened, and the sense coil should generate electricity. The technical solution disclosed by the present invention is a horizontal solution. The support assembly is arranged in a horizontal direction. This embodiment is a technical solution improved on the basis of the third embodiment of the permanent magnet shielding device. In this embodiment, the part of the lion thief and the third real side or the inspection part, please refer to the second embodiment for the disclosure of the valley or the principle. The description of the sexual description should also be made as the content disclosed in the present embodiment, which will not be repeatedly described herein. As shown in the twentieth-figure, the disk-shaped permanent magnet thin shielding device of the present embodiment further includes an electromagnetic generating module 344 disposed on the cylindrical magnetic core 342. The electromagnetic generating module 344 used in this embodiment includes an intermittent current generating circuit and an electromagnetic coil. When the electric riding circuit intermittently discharges a current to the electromagnetic wire, the electromagnetic coil generates a magnetic field. Since the intermittent current generating circuit and the electromagnetic coil can adopt the contents disclosed in the prior art, the magnetic field strength of the secret power generating device can be changed in the rotation of the rotating button wire of the real side towel, so that the power generating device is generated. Inductive current, at the same time, the induction coil also inevitably produces a companion magnetic field to attract the rotating obscuration group, which increases the resistance to the rotation of the 201203806 shading module. By the above-mentioned improvement in the third embodiment of the Yongyun shielding device, as shown in the twenty-second diagram, in order to reduce the attraction force of the associated magnetic field generated by the induction generating coil to the shielding body, it can be given to the electromagnetic generating module. The electromagnetic coil provides an intermittent current to generate a magnetic field opposite to the associated magnetic field of the induction generating coil, the magnetic field being conducted by the cylindrical magnetic core 342 to the butterfly end face of the rotating shielding module to make the butterfly The end body reaches the instantaneous magnetic saturation, and the attractive force of the accompanying magnetic field on the shielding body is weakened. Helps to rotate the rotating motion of the shield. This embodiment is a technical solution improved on the basis of the third embodiment of the permanent magnet shielding device. φ The parts appearing in this embodiment are identical or similar to the third embodiment. Please refer to the disclosure of the second embodiment. Or the understanding of the principle description should also be made as the content disclosed in the embodiment, which will not be repeatedly described herein. As shown in the twenty-third figure and the twenty-fourth figure, the rotating shielding module 32 adopts a multi-layer silicon steel sheet laminated structure, and the multi-layer silicon steel sheet laminated structure is continuously extended by a steel sheet metal structure. The disk-shaped permanent magnet 33 includes two circular end face magnetic poles, an outer cylinder surface, and a central circular hole; the rotating shielding module is mounted on the fixed mandrel by a rotating connecting member; Inductive power generating devices 35 are provided on both sides of the disc-shaped permanent magnets 33; there is a power input wheel mounted with the rotating connecting members. In order to facilitate the rotational movement of the rotating shield, a magnetic sleeve 346 is disposed between the fixed mandrel and the disc-shaped permanent magnet, and the magnetic sleeve 346 penetrates the N, S pole faces of the disc-shaped permanent magnet. The butterfly end face body is magnetically connected to the magnetic conductive sleeve 346; an electromagnetic generating module 344 is disposed on the magnetic conductive sleeve 346. It is worth mentioning that the technical solution disclosed in the third embodiment of the above permanent magnet shielding device is a horizontal solution, but an established solution can also be designed. In the vertical solution, the supporting members are arranged in a vertical direction, and the connection of other parts is possible. The relationship remains the same. A fourth embodiment of a permanent magnet shielding device and a power generating device using the fourth embodiment of the permanent magnet shielding device:

[SI -15· 201203806 As shown in the fifteenth and twenty-fifthth drawings, the double-plate type shielding device of the ring-shaped permanent magnet of the present embodiment is provided with a shouting setting that the shielding device has a frame 41. The frame 41 is provided with a horizontal center fixed shaft 42. The central fixed shaft 42 is mounted with an annular permanent magnet 43. The annular permanent magnet 43 includes two annular magnetic pole faces, an outer cylindrical surface and a central circular hole. A plate-type rotating shielding module 44 is disposed on the left magnetic pole surface of the annular permanent magnet 43, and another plate-shaped rotating shielding module 45 is disposed on the right magnetic pole surface of the annular permanent magnet; the two plate-type rotating The armature group 44 is connected by a bridge of the magnetically conductive bridge 46. The aforementioned two-shirt type shield modules 44, 45 are mounted on the central fixed shaft 42 by a rotary joint 47. The outer column of the permanent magnet μ is provided with a cylindrical magnetic conductive wall 48 corresponding to the position, and the plate-shaped rotating shielding module 44, 45 is magnetically connected with the cylindrical magnetic conductive wall 48. The bottom end of the cylindrical magnetic conductive wall 48 is supported by The crucible 49 is mounted on the base of the aforementioned frame μ. The cap_reading frame 49 of the present embodiment can be made of a non-magnetic material such as a lake flap, a slag alloy, a steel, or a carbon fiber. In the embodiment, the above-mentioned plate type rotating shielding module is in a fan shape, and the fan-shaped cross-section of the plate-type rotating shielding modules 44 and 45 is in a shape of a dome, and the fan-shaped surface angles of the two plate-type rotating shielding modules 44'45 are all 18〇. . In the embodiment, the two plate-type rotating shielding modules 44 and 45 are the same in material, size and shape. The bridging ribs 46 may be one piece or a plurality of evenly distributed, and the bridging ribs 46 are arranged in two plates. Rotate between the outer curved edges of the masking modules 44,45. In this embodiment, two rotating connecting members are further disposed on the two plate type rotating shielding modules 44 and 45. The rotating connecting members are fixedly connected with the plate rotating shielding modules 44 and 45, and the rotating connecting members are respectively connected. A limit bearing 410 is disposed in each of the frames. The above structure can realize the rotational connection between the plate type rotating shielding modules 44 and 45 and the central fixed shaft 42. In addition, the power input wheel 411 and the rotating connecting member are mounted; in the embodiment, the power input wheel 411 is a pulley; in the embodiment, the annular permanent magnet 43 is magnetized in the end direction, and the left end of the annular permanent magnet 43 is set. The N pole and the S pole at the right, the distance between the N pole surface of the ring permanent magnet 43 and the slab rotation shielding module 44, 45 and the distance from the s pole surface of the annular permanent magnet to the slab rotation shielding module 44, 45 The value is equal, and the distance value is usually (^~0.8mm 'preferably' 〇8mm in this embodiment. -16· 201203806 This embodiment uses two non-magnetic bridge ribs 46 to rotate the two plate type shielding modules 44, 45 is connected into one body, the aforementioned bridging ribs 46 can be made of non-magnetic materials such as plastic, aluminum alloy, stainless steel, carbon fiber, etc.; the ribs* improve the rigidity and rotational stability of the slab rotating shielding module ^ 45 Moreover, the structure effectively improves the magnetic field utilization efficiency of the annular permanent magnet ^, thereby improving the magnetic energy conversion efficiency. As shown in the twenty-seventh figure, the embodiment adopts the oblique rotation of the above-mentioned plate type rotating shielding module. A cylindrical magnetic conductive wall 48 is disposed outside, and the cylindrical magnetic conductive wall has a magnetic conductive wall main body 425. Two annular guide edges 424 are disposed on the left and right circular end faces of the magnetic conductive wall main body 425. The annular magnetic guiding edges 424 respectively correspond to the positions of the two slab rotating shielding modules 44 and 45. A gap 412 is provided between the slab rotating shielding modules 44 and 45 and the annular magnetic guiding edge 424. The groups 44, 45 and the cylindrical magnetic conductive wall 48 are magnetically connected, and the 妗2 can ensure the 秘 秘 秘 秘 44 44 44 44 44 44 , , , , , , , , , , , 44 44 44 44 44 44 44 44 Turn _ ' _ 永 杂 _ _ _ flux changes, produce electrical energy output; the aforementioned plate-type rotating shielding module 44, 45 and the cylindrical magnetic conductive wall 48 constitute the original transformation of the creation. In the continuous rotation process, the outer arc edges of the plate-type rotating shielding modules 44, 45 and the two annular magnetic guiding edges 424 of the cylindrical magnetic conductive wall 48 maintain an optimal magnetic gap. Preferably, in the embodiment, the aforementioned magnetic gap is between (U - lmm, so that the plate rotation is shielded The modules 44, 45 and the cylindrical guide _48 constitute a complete _ force line channel. As shown in the second ride, when the two slabs are turned, the shield modules 44, 45 will have the magnetic field of the annular permanent magnet and the s pole surface. When shielding, the magnetic lines 414 of the N pole of the annular permanent magnet 43 cannot penetrate the corresponding plate rotation shielding modules 44 and 45, and only the magnetic conductive channels between the patch layers in the shielding module 44, 45 are rotated along the plate. The distribution of the 'partially upwardly distributed magnetic lines of force is introduced into the other plate-shaped shielding die_ by the cylindrical guide _48 which is magnetically connected by the non-plate type rotating ship module 45, and finally leads back to the pole-shaped portion of the annular permanent magnet 43S. Because there is no guide channel, the magnetic field lines are loosely distributed by the magnetic lines of force, and finally lead along the center line of the permanent magnets.

FSJ -17- 201203806 The ring-shaped permanent magnet shielding device of the present embodiment can be applied to a power generating device. The design of the power generating device is to connect a power input wheel 411 to a driving motor, and drive the plate-type rotating shielding module by driving the motor. 44, 45 rotation; an induction power generating device 415 corresponding to the position of the annular permanent magnet 43 is mounted on the aforementioned frame, and the induction power generating device 415 is a device with an induction coil. When the slab rotation shielding modules 44, 45 are continuously rotated at a certain rotation speed, each time the slab rotation shielding modules 44, 45 pass the position of the induction power generating device 415, the magnetic field strength of the induction power generating device will change. The magnetic flux changes and generates electrical energy, and the electrical energy is output by the inductive power generating device 415. The induction power generating apparatus 415 used in the present embodiment includes a conventional induction core, an induction generating coil, and the like. The rotating connecting member 47 can position the plate-type rotating shielding modules 44 and 45 to ensure that the distance between the annular permanent magnets 43 and the plate-type rotating shielding modules 44 and 45 is equal, and the plate-shaped rotating shielding modules 44 and 45 are ensured. The rotation is smooth; the positioning problem of the slab rotation shielding module 44 and the phantom on the central fixing shaft 42 is solved by two limit bearings mounted in the rotary connecting member 47; the rotating connecting member is integrally made of stainless steel (or Made of aluminum alloy) 'will not be attracted by permanent magnets, easy to install. In this embodiment, a plate-type rotating shielding module 44, 45 is disposed on each of the two magnetic pole faces of the annular permanent magnet 43, and a bridge rib 46 is disposed between the two-plate rotating shielding modules 44 and 45, so that two plates can be realized. The rotating shielding module 44, 45 rotates around the central fixed shaft 42. The two-plate rotating shielding module 44, 45 of the present invention is coaxially equidistant with the annular permanent magnet 43 and has uniform force characteristics, so that the plate type rotating shielding module When the 44, 45 is rotated, the interference of the annular permanent magnet 43 is small, and only a small force is input through the power input wheel 411, so that the plate rotation shielding modules 44 and 45 can be continuously rotated to change the magnetic flux, thereby generating electric energy. The electric energy is output by the induction power generating device. The annular permanent magnet system of the present embodiment is a ring-shaped permanent magnet. The ring-shaped permanent magnet includes two annular magnetic pole faces, an outer cylinder face, and a central circular hole; the annular cross section is rectangular. The above-mentioned annular permanent magnet adopts a permanent magnet made of neodymium iron boron material, and adopts an end face direction magnetization process, and the two end faces after magnetization ^ m • 18· 201203806 become the two magnetic poles of the permanent magnet, that is, respectively, the N pole, s pole. The permanent magnet has the advantages of low energy consumption and low energy consumption. The twenty-ninth figure of the above-mentioned hybrid rotating shielding module is corrected, and 45 is formed by multi-layer Shishi steel sheet 416, and its thickness is between 5η5 coffee. The number of layers of Shishigang is between 2 and 6 ,, and the most preferred thickness is G 3 mm, and the most preferred is the 〇 layer. The specific production method is to use a paste sheet having a sufficient length to wind the sifter into a multi-layered board, and then use the domain to form a rainbow-shaped curtain, as shown in Fig. 30. The magnetically conductive wall 48 is also formed by a plurality of layers of stone-like steel sheets. The specific shape of the square H is sufficient to lengthen (10) the rotating plate to wind the lining into a multi-layered cylindrical material. The cylindrical magnetic conductive wall, because the molding process does not cut the fibrous structure peculiar to the metal material during the processing, maintains the continuity of the structure, and has excellent impurity-conducting effect and is made of the material. The plate-type rotating shielding module has the balance, the material f is uniform, the material is easy to be taken, and one or more magnetic flux lines are established for the magnetic field, so that the magnetic lines of the ring-shaped permanent magnet (fourth) to the eight poles form a magnetic circuit. In the embodiment, the plate type rotation shields the ___ sector shielding plates, and the fan-shaped shielding surface angle of the fan-shaped shielding plate can be set according to actual needs, for example, 3 turns. 45. 9, 〇. 6, 〇〇, 180 °, etc., 18 〇 is selected in this embodiment. . Referring to the twenty-sixth and thirty-th-th, in order to reduce the magnetic flux leakage, the weight of the rotating shielding module is reduced. The high-magnetic effect of the rotating shielding module is provided in the aforementioned towel core and the fixed shaft casing is provided with a magnetic shielding sleeve. The sleeve 418 is mounted on the center fixed shaft 42 and the annular permanent magnet 43 and penetrates the N and S pole faces of the annular permanent magnet 43. The two ends of the magnetic conductive sleeve are magnetically connected to the plate-type rotating shielding modules 44 and 45. The two ends of the magnetic conductive sleeve 418 are provided with contact surfaces 419 corresponding to the plate-type rotating shielding modules 44 and 45. The magnetic conductive sleeve 41°8 and the aforementioned plate type __ group 44, 45 alkali lead turn; when the plate type lying cover group 44, 45 shields the partial magnetic field of the annular permanent magnet 43, the magnetic field lines of the N pole of the partial magnetic field 42〇 can not penetrate the distribution of the magnetic permeability between the layers of the slab-type turn-to-pure group 44, 45, Qiu along the plate-type rotating masking die 201203806 group 44, 45, where _ up, and along The plate type rotating shielding module 45 and the cylindrical magnetic conductive wall 48: = the shielding module 44 forms a magnetic conductive circuit to return the s pole of the magnetic field; wherein - part of the magnetic field, along the plate type rotating shielding module 45, the magnetic guiding sleeve 418 and another plate type rotation cover: the magnetic circuit formed by the module 44 leads back the s pole of the magnetic field; ensures that the magnetic circuit is smooth, reduces the rotational resistance of the rotation shielding modules 44, 45, effectively increases the magnetic flux, and increases the magnetic field. The shame rate 'reduced magnetic field loss' increases the output power of the electrical energy. The aforementioned magnetic conductive sleeve 418 is made of a magnetically permeable material such as iron or tantalum steel sheet.

As shown in the twenty-sixth and thirty-second diagrams, the electromagnetic conducting module 421 is mounted on the magnetic guiding sleeve 418, and the electromagnetic generating module 421 is mounted on the magnetic guiding sleeve 418 and the annular permanent magnet 43. The 'between' and the positioning collar mounted on the electromagnetic generating module 421_ seem to be fixed. In the power generation process, the aforementioned induction power generating device still exerts an attractive force on the plate type rotating shielding module 44, 45, hindering the plate type rotating shielding module material and the milk rotation; and, on the electromagnetic generating module 421 The intermittent input current 'the plate-type rotating shielding module 44, 45 generates an electromagnetic field whose N-pole corresponds to the N-pole of the annular permanent magnet 43, and the S-pole of the electromagnetic field corresponds to the S-pole of the annular permanent magnet 43 so that the ring-shaped ring The magnetic lines 423 in the permanent magnet phantom N-pole introduction plate-type rotating shielding modules 44, 45 are instantaneously saturated and penetrate the plate-type rotating shielding module 44, 45 ' between the induction power generating device 415 and the plate-type rotating shielding module 44, 45 Forming a repulsive magnetic field of the same magnetic pole can reduce the attraction of a portion of the inductive power generating device 415 to the plate-type rotating shielding modules 44, 45, and contribute to the rotational movement of the plate-type rotating shielding modules 44, 45. The electromagnetic generating module 421 used in the embodiment includes an intermittent current generating circuit and an electromagnetic coil. When the intermittent current generating circuit inputs an intermittent current to the electromagnetic coil, the electromagnetic coil generates an electromagnetic field. Both the intermittent current generating circuit and the electromagnetic coil can be disclosed in the prior art and will not be described again. Referring to the thirty-third figure, as shown in the thirty-fourth figure, the shielding body in this embodiment may be disposed as two butterfly-shaped rotating shielding modules 405' and connected by at least two bridging ribs 406.

ESJ -20- 201203806 In one piece, the butterfly-shaped rotating shielding module 405 is composed of two scalloped surfaces arranged in an axis symmetry, and the central angle of the scalloped surface is 90°. The aforementioned butterfly-shaped rotating shielding module 4〇5 The cross-section of the two butterfly-shaped rotary shielding modules in the present embodiment is the same in material, size and shape. The aforementioned bridging ribs 406 can be evenly distributed, and the bridging ribs 4 〇 6 are set. Between the outer curved edges of the two butterfly-shaped rotating shielding modules, β is worth mentioning: the technical solution disclosed in this embodiment is a horizontal solution, and the central fixed shaft is arranged in a horizontal direction; the creation can also be designed. In the vertical scheme, the central fixed shaft is arranged in the vertical direction, and the connection relationship of other parts is unchanged except that the support structure needs to be changed. The fifth embodiment of the permanent magnet shielding device and the power generating device constructed by the fifth embodiment of the permanent magnet shielding device: as shown in the fifteenth, twenty-sixth, and thirty-seventh embodiments, the embodiment adopts the disk The permanent magnet half-shell shielding device comprises a frame 51, the frame 51 is provided with a central fixed shaft 52, and the touch-type 51-characterized plate has a Nayong _ 53, Na permanent magnet 53 includes two One end face of the disk-shaped permanent magnet 53 is covered with a half-shell fixed shielding body 54. The other end face of the disk-shaped permanent magnet 53 is covered with a rotating shielding module 55; the rotating shielding module 55 The first half-shell fixed shielding body is magnetically connected; the rotating shielding module 55 includes a butterfly end surface and a curved side wall; the rotating shielding module is provided with a rotating connecting member 56. The rotating shielding module 55 is rotated by the connecting member. The brother and the center are positioned to rotate the shaft 52. The central fixed shaft 52 and the disc-shaped permanent magnet 53 are disposed in the same axial center. In the embodiment, the frame 51 is composed of a plurality of fixing posts 511 and a plurality of bracket plates 512 and 513, and the frame is made of a non-magnetic material. (Examples of alloy reduction, no steel recording, etc.). The central fixing wire 52 is installed on the bracket plate 512. If the technical scheme of the vertical layout is adopted, the central fixed shaft Μ belongs to the hanging installation. If the technology of the mining ship board is transferred, the towel core shaft is installed in the (four) type, the implementation is as follows Implementation of technical solutions for vertical layout. A half-shell fixed shielding body (5) is arranged between the bracket-shaped permanent magnet 53 and the bracket plate on the bracket plate 5 at the bottom of the frame 51. (21) -21 - 201203806 54 semi-finished fixed hull 54 and bracket plate (10) It is still fixed by fastening the parts. In the present embodiment, the disc-shaped permanent magnet 53 is made of a snagging iron boron material, and is a disk-shaped permanent magnet, including two upper and lower circular end faces and an outer cylinder; the permanent magnets are oriented along the end face (or axial direction). The two circular end faces of the disc-shaped permanent magnet 53 are N poles and S poles respectively. The upper end surface of the disk-shaped permanent magnet 53 is covered with a rotating shielding module %, and the lower end magnetic pole is provided with a half-shell phase-dependent body rotating contact % to be magnetically connected to the half-shell fixed shielding body 54. In the present embodiment, the half-shell fixed body% lion multi-layered dream steel sheet stacking structure ′ includes a circular end surface 541 and a cylindrical side wall 542 having a half-shell structure. The rotating shielding module 55 adopts a multi-god steel sheet dust-collecting structure, and includes a butterfly-shaped end surface 551 and a curved side wall 552'. Preferably, the lion end surface 551 of the 'rotating shielding module 55 is formed by two scalloped surfaces symmetrically arranged, and the fan shape The center angle of the face is 9 inches. . The radius of curvature of the curved side wall 552 in the rotating masking module % is the same as the cylindrical fiber M2 _ rate radius in the half-shell fixed shielding body 54--the best of the genius, _ magnetic connection, The aforementioned magnetically conductive connection lie group 55 maintains an optimum magnetic gap (usually 1 〇 〇 mm) in the continuous _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ The rotating shielding die component is further provided with a lying connecting member 56. The rotating connecting member 56 is made of a non-magnetic material in the shape of a circular tube, the lower part is fixed to the rotating shielding module 55, and the upper part is provided with a power input pulley 57, by the upper bearing and The lower bearing is rotatably mounted with the center fixed shaft 52. In this embodiment, the technical solution of the vertical layout can be compiled and the technical solution of the secret layout can be adopted. For the convenience of description and understanding, only the technical solution of the vertical layout is described herein. As shown in the thirty-eighth figure, the disc-shaped permanent magnet half-shell shielding device in the present embodiment can be applied to a power generating device: a plurality of inductive power generating devices 5〇3 are still disposed on the bracket plate of the aforementioned frame, and the sensing The power generating device 503 is disposed above the end surface magnetic pole of the disk-shaped permanent magnet 53 on the side of the rotating shield module 55. The inductive power generating apparatus 5〇3 of the present embodiment includes a conventional inductive core, inductive power generation_' belongs to a conventional technique, and j; a miscellaneous description. When the rotating thief group % rotates continuously at a certain speed, the magnetic field strength around the induction coil will continuously change, and the induction coil [Sj 22 - 201203806 will generate electricity by induction. A power input wheel 57 is mounted with the aforementioned rotary joint member. The power input wheel 57 can be dynamically coupled to a motor by a belt drive mechanism, and the motor is driven to rotate the shutter module 55 continuously.

As shown in the thirtieth figure, the thirty-ninth figure, and the fortieth figure, in order to improve on the basis of the present embodiment, the butterfly end faces of the 'rotation shielding module are axially symmetrically disposed. The fan-shaped faces 51〇6 constitute the 'central angle of the aforementioned fan-shaped surface is 6〇. —9〇. The best center angle of the scalloped surface is 90°. In order to maintain the optimal magnetic relationship and reduce the feeding power of the rotating shielding module, the above-mentioned rotating shielding module is provided with a ring-shaped pneumatic bearing 5G8, and the aforementioned frame is provided with 509. The aerodynamic bearing of the present invention may also be referred to as an air-floating guide rail, and the compressed air 'a pneumatic bearing body is provided with a plurality of compressed gas injection holes, and the annular pneumatic bearing system and the gas-supporting body are provided with a rail floating ring> ;, the two _ Chi small gap. The air float guide is a conventional technique and will not be described here. As shown in the fortieth-figure diagram, in the present embodiment, the rotating shielding module % adopts a multi-layer Shishi steel sheet laminated structure. The foregoing multi-layer patch lamination structure is composed of a thin steel sheet continuously extended by a paste metal structure. The thickness of the 'pre-finished butterfly' is in the range of 4 to 60 layers in the range of the most suitable thickness system. The most preferred layer number is the layer (1). The specific production method is to use a hollow disk with sufficient length __ plate to make the __ die and wind it into a plurality of layers, and the woven fabric is cut into a shape as shown in the first figure. The Cheng-type process has the unique magnetic properties of the metal-based material, and has excellent magnetic permeability. The half-shell glide shields are also manufactured using the same process.

[SI as a further improvement in this embodiment, as shown in the forty-second figure, in order to reduce the magnetic flux leakage, ^ lightly rotate the visor group 55, to improve the fine effect, the center of the _ cedar device is fixed A magnetically conductive sleeve is disposed between the shaft 52 and the disc-shaped permanent magnet S3. The guide cylinder 540 extends through the N and s pole faces of the disc-shaped permanent magnet 53 and is inside the butterfly end face of the rotating shielding module %. An electromagnetic generating module mo is disposed coaxially with the magnetically conductive sleeve (10) and the magnetically conductive sleeve (10) and the disc-shaped permanent magnet of the above-mentioned -23-201203806. In this embodiment, the rotating cover is fixed from the structure. The lion end face of the j module 55 and the magnetic permeable sleeve $(10) have an efficient magnetic conductive connection. The magnetic conductive connection described in the present embodiment means that the two butterfly end faces are guided and simplified during continuous rotation. The upper and lower end faces of 540 maintain the optimal magnetic gap (usually ~1 mm), and the butterfly end face and the magnetically permeable sleeve form a complete magnetic flux path. The twelfth figure shows the disc-shaped permanent magnet 53 in the free state of the single magnetic field line distribution; fine fourteen shows the disc open / permanent magnet 53 with a magnetic sleeve The distribution of magnetic lines of force after the cylinder 54 is rotated and the shielding module 55 is rotated. At this time, the magnetic lines of force along the side wall of the rotating shielding module 55 and the two magnetic paths of the magnetic guiding sleeve 540 are distributed more evenly. Thereby, the thickness of the butterfly end face can be reduced. The dotted line with an arrow indicates the direction of the magnetic field line. As shown in the forty-fifth figure, the rotary shielding module 55 in this embodiment can make the induction power generation equipment week in the rotation. The magnetic field strength is constantly changing, so that the power generating device generates an induced current, and the 'inductive power generating coil also inevitably generates a companion magnetic field to attract the rotating shielding module 55, which increases the resistance to the lion of the rotating shielding module 55. The gravitational force of the associated magnetic field on the shielding body can provide an intermittent current to the electromagnetic coil in the electromagnetic generating module 53A to generate a magnetic field opposite to the associated magnetic field of the induction generating coil, the magnetic field is provided by the magnetic shielding sleeve The cylinder 540 is transmitted to the butterfly end surface of the rotating shielding module 55, so that the butterfly end surface achieves instantaneous magnetic saturation, and the attraction force of the accompanying magnetic field to the shielding body is weakened. The electromagnetic generating module 53 本 used in the embodiment includes a 嶋 current generating circuit and an electric coil. When the intermittent current generating circuit inputs a current to the electromagnetic coil, the electromagnetic The coil generates a magnetic field. The intermittent current generating circuit and the electromagnetic_ can be used in the prior art and are not described in detail. It is worth mentioning that in the present embodiment, the aforementioned rotating shielding module can be adjusted as needed. The structure of the rotating shield module can also be composed of a semicircular end surface and an arcuate side wall. Preferably, in the permanent magnet shielding device, the first embodiment, the second embodiment, the third embodiment, the fourth embodiment, and the The rotating masks in the fifth embodiment are all in a floating state. In the present invention, the m -24 - 201203806 suspension state refers to a state in which the rotating shield is subjected to various forces and the resultant force is zero or the resultant force tends to zero. The second embodiment of the permanent magnet shielding device can be applied to the first embodiment of the driving device: as shown in the 46th and 47th, the design of the first embodiment of the magnetic driving device is The driving device has a health-setting circle, and a fixed platform 1002 is disposed in the Wei frame, and a linkage frame is mounted on the fixed platform 1002, and a power output device is installed under the fixed platform 1002, and the foregoing linkage The frame is composed of a left linkage frame 1003 and a right # linkage frame _ two parts. The aforementioned left linkage frame 10〇3 and the right linkage frame brain are respectively mounted by the two guide columns 1005 and the device age surface, and the guide column is fixed at the lower end. The top of the platform is dirty, and the top end of the screen is mounted on the left interlocking frame 1003 and the right frame of the brain + _4 妓. The permanent magnet shielding device is attached. The first embodiment, the first embodiment, and the second embodiment are disclosed. a permanent magnet shielding device 1007; the lower end of the central fixed shaft surface of the permanent magnet shielding device is fixed in the upper surface of the fixed platform surface and fixed to the device rack top cover 1006; the permanent magnet shielding device central fixed shaft There is no power input wheel 1〇〇9 in the upper and lower parts, and the power input to the outside of the wheel surface is connected to the motor. The motor is rotated by the wire power to test the rotation of the wheel surface. In the above-mentioned left and right linkage frames 1004 (4), a phase-shaped permanent magnet (6) is mounted at a position corresponding to the permanent magnet circle, and the hybrid and permanent magnets 1下1〇 at the lower end of the semi-circular permanent magnet 1011 are mounted. The magnetic poles at the upper end have the same polarity. 'The left lion frame surface and the right linkage frame are separated from the permanent magnet ι〇ι〇, and each has a phase magnetic 峨ωΐ2; the left-left linkage frame 1003 and the right linkage 1GG4 The lower age is connected by the rotating shaft of the power output device of the _ handle and the secret power output device, and the two ends of the rotating shaft are mounted on the frame of the power output device by rotating the bearing, in the foregoing rotation The shaft is cut into the ampoule with the power output wheel 1〇16 1 to select the ground. In order to ensure the rotation of the rotating shaft 1014 is stable, the flywheel 1017 can be installed in the middle of the rotating shaft -2525- 201203806» The working principle of this embodiment _: When the power output wheel 1 〇16 drives two rotating shades __ turn to turn ' When the two rotating shielding modules are completely on the right side of the central fixed axis, the two rotating shielding modules completely complete the right half of the hydromagnet 1G1G; at this time, the semi-circular permanent magnet 1011 on the frame surface of the left county is subjected to the permanent magnet. The repulsive force of the magnetic field in the left half of the face, the semi-circular magnet block (9) 2 on the left linkage frame is attracted by the magnetic field in the left half of the Yonger face. Under the action of these two forces, the left chicken frame 1〇〇 3, moving up along the guiding column, and on the other hand, since the two rotating shielding modules completely occlude the right half of the permanent magnet, the semi-circular permanent magnet ι〇ιι on the right linkage frame surface will be The moving mask module generates a downward attraction, and at the same time, the permanent magnet surface loses the attraction to the semi-circular magnet block (4) on the right linkage frame 1004 by rotating the shielding module, resulting in the right linkage frame. It is difficult to move down the guide column 1005 under the attraction of the permanent magnet i (10) and its own gravity. In the same way, when the two rotating shielding modules completely shield the left side of the permanent magnet coffee; the left _ turn to the right, the right joint _ move upward. The father replaces the area of the permanent magnet surface by switching the shielding module, so that the left linkage frame and the right Wei can be turned into no movement, and the rotation axis 1014 of the power transmission device is driven by the Lin-Ban linkage mechanism. Thereby driving the i to achieve power output. The first embodiment and the third embodiment of the foregoing permanent magnet shielding device are applied to the second embodiment of the driving device. (4) The example can be shown in the figure. The driving device has a device rack in which x is mounted. There is a power output device ” "smuggling frame" in the Gu Ding platform below the two parts _, turn left by the left crane to the fine frame of the linkage frame, the fine line recorded in the fixed flat top and the top of the device rack Cover 2006 fixed, fine and right linkage in the aforementioned left linkage frame

[SJ -26- 201203806 Frame 2004 'The position is vertically installed with the first - implementation of the attached ring Yong Yun shadow attack attack 2007; the lower end of the shielding device center fixed shaft 2〇〇8 is fixed at the upper end of the fixed platform and the device shaft cover Na fixed; yue recorded towel ^ fixed shaft fiber with _ a power input wheel chat 'sports input wheel stupid external _ _ money, by driving the motor to drive the power input wheel 2009 rotation, thereby driving the brain shielding module Rotational motion; a semi-circular permanent magnet 201 is mounted at each of the positions of the left and right reciprocating frame and the ring-shaped magnet and the ring-shaped permanent magnet 2 at the lower end of the semi-circular permanent magnet 2011 _ upper end _ pole polarity is the same; in the foregoing left crane frame fine and right linkage frame article base j ring permanent magnet thin corresponding position is installed with a semi-circular magnet block 2 〇 12, narration left linkage frame 2003 and right The lower ends of the linkage frame 2004 are respectively connected to both ends of the rotating shaft 2014 on the power output device by a crank linkage mechanism 2013, and both ends of the rotating shaft are mounted on the frame of the power output device by rotating bearings. In the rotation shaft of the power output gear mounted Na, New York is rotated ⑽ dynamic stability, the flywheel may be mounted on the rotation unit. The working principle of the embodiment is as follows: when the power input wheel lion drives the rotating shielding module to rotate, and the right half of the annular permanent magnet 2_ is completely shielded; at this time, the semi-circular permanent magnet on the left linkage frame _ is subjected to The repulsive force of the magnetic field in the left half of the ring-shaped permanent magnet lion, the semi-circular magnet block 2〇12 of the left-linking frame 帛2003 _L is subjected to the engraving force of the magnetic field of the left half of the ring-shaped permanent magnet 2_ in these two forces _ _ Next, the left lion_fine moves along the guide column 05 upwards. On the other hand, the right half of the ring-shaped permanent magnet is shielded by the rotating shielding module. The semi-circular permanent magnet on the right linkage frame 2〇〇4 of Xianyue said · It will rotate the mask and reduce the downward attraction. At the same time, the ring-shaped permanent magnet on the side of the rotating shield module loses the attraction of the Weike magnet block on the right linkage frame, resulting in the right The linkage frame 2004 moves downwards under the action of the attraction of the ring-shaped permanent magnet lion and its own gravity/0 to the column 2〇〇5. Similarly, when the shielding module is rotated, the left half of the ring-shaped permanent magnet is completely Wei; the left manuscript is moved down and the right crane is _-up

f SI -27- 201203806 Mobile. The rotation of the rotating shielding module shields the area of the annular permanent magnet, so that the left linkage frame 2003 and the right linkage frame 2004 are continuously staggered up and down, and the crankshaft linkage mechanism drives the rotation shaft of the power output device to rotate, thereby driving The power output wheel rotates to realize the magnetic power output. A third embodiment of the present inventive driving apparatus: Referring to Figures 49 to 52, this embodiment relates to a butterfly magnetic driving device for a disc-shaped permanent magnet, which comprises a frame 3〇〇1 A support frame 3002 is mounted on the frame 3〇〇1, and a center fixed shaft 3〇〇3 is disposed on the support frame 3002, and a disc-shaped permanent magnet is mounted on the center fixed shaft 3003. The disk-shaped permanent magnet 3〇〇4 includes an N-pole circular end face magnetic pole (right end face) and a s-pole circular end face magnetic pole (left end face), and the disk-shaped permanent magnet f 3004 is provided with a rotating shielding module The above-mentioned rotating shielding module Na includes an N-pole butterfly shielding plate 3006 disposed in parallel with the N-pole circular end surface magnetic pole of the disc-shaped permanent magnet 3〇〇4, and the aforementioned disc-shaped permanent magnet 3〇〇4 The s-pole butterfly shielding plate 3007 in which the pole-shaped end faces are arranged in parallel, and the bridged magnetic-guiding plates 3〇〇8 connecting the two aforementioned butterfly shielding plates. The butterfly shielding plate described in the present embodiment is composed of two sector-shaped surfaces which are arranged in an axisymmetric manner, and the circle of the sector surface has an angle of 60 90. Preferably, the embodiment adopts a central angle of the scalloped surface of 9 〇. The butterfly-shaped shield module 3005 is mounted on the central fixing shaft 3〇03 by a rotating connecting member 3009, and a synchronous driving mechanism is mounted on the rotating connecting member 3009, and the synchronous mechanism can be realized. Rotating the intermittent rotation of the shielding module 5; providing a reciprocating movable magnet linkage 3_ on the frame 3 (10) 1 , the distance between the reciprocating movable magnet linkage 3010 and the frame is between 1 and 10 cm, The reciprocating movable magnet linkage frame 3 (10) is connected to the frame through a sliding t-frame, and the reciprocating movable magnet linkage frame 3 is connected by a crank "dry mechanism 3 (m is connected with a power output pumping 3, 12 The power output wheel and the power output shaft 3〇12 are installed. The power output shaft is provided with a flywheel mechanism 为 for maintaining its rotation stability; the reciprocating dynamic magnet linkage frame is along the movement axis of the frame slide mechanism Line (left and right reciprocating motion) and the aforementioned disk-shaped permanent magnet N-pole circular end face magnetic pole

[SI -28 · 201203806 The normal direction (parallel to the central fixed axis) is parallel; at each end of the reciprocating dynamic magnet linkage 3010, a fixed plate 3015 parallel to the disc-shaped permanent magnet 3 (8) 4 _ end face is placed. A _body 3 〇 16 is disposed on each of the two fixing plates 3015. The moving magnet 3 〇 16 includes an N-terminal magnetic pole (left end surface) and an S-terminal magnetic pole (right end surface). The foregoing moving magnet in this embodiment The end face is fan-shaped, and the central angle of the fan shape is 6 inches. ~9〇. Preferably, the embodiment adopts a sector center angle of 90. Dynamic magnet. The moving magnet of the right end of the reciprocating movable magnet linkage frame 3〇1〇 is disposed on the right side of the N _ and the surface miscellaneous of the front Zhao permanent magnet, and the N pole surface magnetic pole of the moving magnet and the N of the aforementioned Na permanent magnet 3〇〇4 The polar circular end magnetic pole is oppositely disposed. The moving magnet of the left end of the reciprocating movable magnet linkage 3_ is disposed on the left side of the magnetic pole of the disc-shaped permanent magnet 3004, the S pole surface of the moving magnet, and the s pole of the s pole. The butterfly shielding board is in the position. The present embodiment is the same as the above-mentioned movable plate 3〇16 by bonding and the central fixed shaft 3003 @1. The permanent magnets 3〇〇4 and the moving magnets 3〇16 are of the same end-face magnetization, preferably, the front _ 3G16 敝 small-stitch permanent magnet _ 1/4. In the embodiment, the left and right crane magnets are diagonally disposed, and the left movable magnet corresponds to the butterfly shielding plate on the left side of the disc permanent magnet, and the right moving magnet and the magnetic pole surface on the right side of the disc permanent magnet. correspond. - before the magnetically permeable sleeve is mounted on the center fixed shaft, the magnetically permeable sleeve 3 π is mounted between the aforementioned central fixed shaft 3 〇〇 3 and the disc-shaped permanent magnet 3 〇〇 4 The sleeve is connected to the two ends of the front plate and the front plate. The magnetically conductive connection as described in this embodiment refers to two butterfly shielding plates 3 (8) 6 at the ends of the magnetic conductive sleeve 3017 and the disk-shaped permanent magnets 3〇〇4 when the rotating shielding module is in the rotating process. A magnetic gap 3018 is provided between 3〇〇7 'two butterfly shielding plates 3〇〇6, 3〇〇7 and magnetic guiding sleeves 3〇1<7 both maintain an optimal magnetic gap 'the distance of the magnetic gap Rotating the shielding module 〇 and the magnetic guiding sleeve 3017 between 〇.〇1~lmm constitute a complete magnetic flux path. An electromagnetic generating module window is mounted on the magnetic guiding sleeve, and the electromagnetic generating module

[SI -29-201203806 3(10) is installed between the aforementioned magnetic conductive sleeve 30Π and the disc-shaped permanent magnet 3〇〇4. The magnetic field generated by the electromagnetic generating module 3019 can make the rotating shielding module 3005 force the two butterfly shielding plates, and the 3007 realizes the instantaneous magnetic saturation, so as to reduce the dynamic magnets on the movable movable magnet linkage frame 3〇ι〇. Lai Jianna’s courage is determined by the depositors. The electromagnetic generation module used in the actual use includes an intermittent current generating circuit, an electromagnetic wire_frame, an electromagnetic coil, and an intermittent current generating circuit that inputs an intermittent current to the electromagnetic coil, the electromagnetic coil generates a magnetic field; the intermittent current generating circuit and The electromagnetic coils can all be disclosed in the prior art and will not be described here.

In order to ensure uniform and stable rotation of the rotating shielding module 3005, the N-pole circular end face magnetic pole of the aforementioned disc-shaped permanent magnet is transferred to the N-pole butterfly shielding plate # distance and the S pole of the disc-shaped permanent magnet brain. The distances from the circular to the s-pole butterfly shielding plates are equal, and the value of the distance is 0.5 to 3 mm 'in this embodiment, 1 mm. Wherein the aforementioned butterfly shielding plate 10 (10) 7 adopts a multi-layered dream steel sheet Wei structure, and the aforementioned butterfly shielding plate has a body wall thickness of between G 5 and 2 Gmm, and the most preferable thickness is 3 mm; the butterfly shielding plate 3_, 3〇〇7 The number of layers of Shixi steel is reasonably selected between 2 and 8〇, the most preferred number of layers is (1) layer ^ specific production method - brand coffin winding: multi-layer, and then use cutting The forming process is added to the sliding shielding body; since the fibrous structure unique to the golden crown material is not cut during the work process, the magnetic permeability is maintained, and the shielding effect is good, and the material is made of the material. Λ f uniform, taking the material "; for the magnetic field to establish - a magnetic flux line fast shielding plate two pieces (10) 9 and the rotating shield module thin butterfly shutter solid connection, in the aforementioned rotating connection member 3009 with bearing thin 7 to achieve Reward (4) 5 嶋 嶋 · off :::: Include two axisymmetrically mounted her compound moving magnet linkage frame by means of a slab sleeve set at the bottom of the f S] • 30- 201203806 with the cylindrical rail installation, such as As shown in the fifty-third figure, the bearing sleeve 3022 is mounted with a straight bearing 3023. In the embodiment, the sliding mechanism described above adopts Na, Ming alloy, non-scale steel, carbon, dimensional, etc. The rotating connecting member is also made of non-magnetic material such as age, gold, non-recorded steel, anaesthetic fiber; in the embodiment, the aforementioned disc-shaped permanent magnet and moving magnet __ lyre, _ The advantage of the material having the low limit of the filament is as shown in the fifty-fourth figure. In the embodiment, the foregoing slide rail mechanism may further comprise two strip-shaped miscellaneous materials which are axially symmetrically t-mounted in the machine red, the foregoing Reciprocating dynamic magnet linkage frame. By setting it at the bottom of the _ moving collar, there is no strip shape, as shown in the fifty-fifth figure. The foregoing sliding rail mechanism in this embodiment may further include two strip-shaped chutes 3026 that are axially symmetrically mounted on the frame. The reciprocating movable magnet linkage frame is provided by a sliding support rail 3027 disposed at the bottom thereof. The strip-shaped chute is installed. In order to realize the rapid intermittent rotation of the rotating shielding module 3005 and improve the rotational displacement accuracy of the rotating shielding module 3〇〇5 to enhance the shielding quality, the embodiment is equipped with a synchronous driving mechanism, and the aforementioned synchronous driving mechanism includes Drive motor (stepper motor), main synchronous wheel, slave synchronous wheel 3028, synchronous toothed belt 3G29 and drive-up weaving road 'pre-legal step wheel fine with the aforementioned rotating joint 3009 women's, the main synchronization of the drive motor The wheel is connected to the slave synchronous wheel 3028 by a synchronous toothed belt 3029. The drive motor is connected with a drive control circuit (known in the art). The rotation interval and the rotation angle of the rotary shielding module 3005 can be preset in the drive control circuit. The rotating shielding module 3005 is instantly controlled by the driving control circuit, and the structure has the characteristics of high displacement precision and good effect. In this embodiment, under the control of the driving control circuit, the driving motor drives the rotating shielding module 3005 to intermittently rotate. The maximum rotating speed of the rotating shielding module 3005 is 3 rpm, and the rotating shielding module rotates 9 times. 〇At least intermittently 〇.05 seconds. In the embodiment, under the control of the driving control circuit, the driving motor can also drive the rotating shielding module 3〇〇5 to perform intermittent reciprocating rotation, and the rotation angle of the rotating shielding module is reciprocating 9〇。 As shown in the fifty-sixth figure, in the present embodiment, the aforementioned crank-link mechanism 3〇1丨 (known technique) m -31 - 201203806 includes the crank 3〇3〇 and the connecting rod selects the aforementioned connecting rod _ articulated with the reciprocating dynamic magnet linkage 3〇1〇, and the aforementioned crank toilet is fixed to the power output shaft 2 . With this structure, the reciprocating movement of the reciprocating movable magnet linkage frame 3 (10) can be converted into a rotational motion and outputted by the power output wheel. In the embodiment, the front and rear reciprocating magnetic _ moving frame has a fine-shaped linkage frame main body, and an SI fixed plate parallel to the circular end surface magnetic pole of the disc-shaped permanent magnet is disposed at each of the left and right ends of the main body of the linkage frame, A fixed cut is installed on the Guding plate, and the branch of the _ is disposed on the front and rear sides of the main body of the linkage. In the embodiment, the aforementioned frame, the branch frame, the central fixed shaft, the rotating connecting member, the sliding rail mechanism, the reciprocating dynamic magnet linkage frame and the like are all integrally used of the valve, the Shao alloy, the non-pound steel, the halogen fiber, and the like. Made of magnetically permeable material. The working principle of the embodiment is: when the rotating shielding module partially shields the disc-shaped permanent magnet, the magnetic field of the disc-shaped permanent magnet that is not shielded at this time generates a magnetic repulsive force on a corresponding moving magnet, and the other The moving magnet attracts the corresponding butterfly shielding plate of the rotating shielding module, so that the reciprocating moving surface touches the horizontally to move horizontally; #Rotating the blocking group needs to continue to rotate when inputting a current to the electromagnetic generating module So that it generates a magnetic field in the same direction as the magnetic pole of the disc-shaped permanent magnet. The magnetic field lines of the magnetic field can realize the instantaneous magnetic saturation of the two butterfly shielding plates of the rotating shielding module, and generate a force repulsing the magnetic field of the moving magnet. Reducing the attraction of the moving magnet on the reciprocating dynamic magnet linkage to the rotating shielding module helps to rotate the shielding module; when the rotating shielding module continues to rotate 90. At this time, the originally repelled moving magnet attracts the corresponding butterfly shielding plate, and the moving magnet originally attracting the butterfly shielding plate is repelled under the action of the disc-shaped permanent magnet, so that the reciprocating dynamic magnet linkage frame is reversed. The direction moves horizontally; the driving motor drives the rotating shielding module to intermittently rotate, so that the reciprocating dynamic magnet linkage moves horizontally along the moving axis of the sliding rail mechanism, and the generated power drives the power output shaft to rotate by the crank link' and finally Output by the power output wheel. As an alternative to the embodiment, the synchronous driving mechanism mounted on the rotary connecting member of the present embodiment can be replaced by a reciprocating rotary driving mechanism. As shown in Figure 57, before

[SI -32· 201203806 Reciprocating rotary drive mechanism includes drive motor (stepper motor), main synchronous wheel, synchronous wheel shifting, synchronous toothed belt hall and axle test 'pre-reliance infantry wheel (four) moving joint installation, the aforementioned The main synchronizing wheel of the drive motor is coupled to the aforementioned synchronizing wheel by a synchronous toothed belt. The driving motor is connected with a driving control circuit (known technology), and the rotation interval and the rotation angle of the rotating shielding module can be set in the driving control circuit, and the driving control circuit controls the rotating shielding module in real time. The structure has the characteristics of high displacement precision and good shielding effect. In the embodiment, under the control of the driving control circuit, the driving motor can also drive the rotating shielding module to perform intermittent reciprocating rotation, and the rotation shielding module has a rotation angle of 90. . The working principle of the embodiment is: when the rotating shielding module partially shields the disc-shaped permanent magnets, 'At this time, Na Yongzao is not subjected to magnetic repulsive force by the _(4) lion and the 働 magnet, and the other is the crane magnet. Corresponding to the rotating mode __ shielding plate, the reciprocating dynamic magnet linkage frame is horizontally moved; when the rotating shielding module needs to rotate in the opposite direction, a current is input to the electromagnetic generating module to generate a magnetic field that is in the direction of the magnetic pole of the disc-shaped permanent magnet. The magnetic field lines of the magnetic field can make the two butterfly shielding plates of the rotating button module realize the hybrid force, and generate a force that repels the magnetic field of the moving magnet, which can reduce the reciprocating type. The attraction of the moving magnet on the moving magnet linkage to the rotating shielding module helps to turn the shielding module age; when the thief group rotates 9 turns in the opposite direction. At this time, the original repulsed moving magnet attracts the lion's new board's wire (four) lion shield plate riding magnet is repelled under the side of the disc-shaped permanent magnet, so that the moving _ body crane frame moves horizontally in the decreasing direction The driving motor drives the rotating shielding module to intermittently reciprocate to realize the reciprocating dynamic magnet linkage moving horizontally along the moving axis of the sliding rail mechanism, and the generated power is driven by the crank connecting rod to drive the power wheel out of the shaft and finally borrow Φ power output wheel output. As one of the alternatives of the embodiment, the reciprocating movable magnet linkage frame of the present embodiment can also be replaced by a reciprocating magnetic bar scale, so that the moving magnet of the hybrid hybrid dynamic magnet linkage can be replaced by a magnetizer. . As shown in the fifty-eighth figure, on the aforementioned frame [si -33- 201203806 set-repenter type magnetism linkage 3〇34, the reciprocating magnetism linkage frame is installed by the slide rail mechanism and the front frame The front stalk guide _ lion frame is equipped with a crank linkage mechanism and a crane force, and a miscellaneous mechanism is arranged on the silk power green; the reciprocating magnet guide linkage 3G34 is along the lion axis of the trajectory rail mechanism. The normal direction of the magnetic pole of the N-shaped circular end face of the disc-shaped permanent magnet is parallel; a magnetic conductive 胄3〇35' is disposed at each end of the reciprocating magnetizer linkage frame, and one end of the reciprocating magneto-optical linkage 3〇34 is The guiding magnet is disposed on a side of the magnetic pole of the N-pole circular end face of the disc-shaped permanent magnet, and the working surface of the magnetizer is disposed over the N-shaped frequency miscellaneous of the disc-shaped permanent magnet, and the surface reciprocating magnetism linkage 3304 The guide magnet of the end is disposed on the side of the 8 pole_end magnetic pole of the disc-shaped permanent magnet, and the working surface 3G37 of the magnetizer is disposed with the aforementioned S_healing plate. The tile-shaped rotating magnetizer of the foregoing embodiment is made of a magnetically permeable material such as ferrite or carbon steel. The working principle of the embodiment is: when the rotating mask module partially shields the disc-shaped permanent magnet, the magnetic field of the disc-shaped permanent magnet that is not shielded is magnetically attracted to a corresponding magnetizer, and the other is _ Between the disc and the disc shape, there is no magnetic field between the magnetizer and the disc-shaped permanent magnet due to the shielding of the butterfly-shaped shield. Under the attraction of the disc-shaped permanent magnet, the reciprocating guide _ rack- The inclined axis of the square; when the rotating group continues to rotate by 90°, the originally shielded magnet is attracted by the disc-shaped permanent magnet, and the reciprocating magnetizer linkage in the opposite direction under the attraction of the disc-shaped permanent magnet Horizontal movement; the driving motor drives the rotating shielding module to intermittently rotate, so that the reciprocating magnetic coupling linkage moves horizontally along the moving axis of the sliding rail mechanism, and the generated power drives the power output shaft to rotate by the crank link' and finally Output by the power output wheel. It is worthwhile to mention: the technical solution disclosed in this detail is a shouting scheme, and the fixed axis of the towel core is set in the horizontal direction; the creation can also design an established scheme. In the vertical scheme, the central fixed axis is set in the vertical direction. The connection relationship of other parts is unchanged except that the support structure needs to be changed. Although the preferred embodiment of the present invention has been disclosed for illustrative purposes, it will be appreciated by those skilled in the art that the scope and spirit of the present invention disclosed by the appended claims are not In the case of various improvements, additions and substitutions are possible. BRIEF DESCRIPTION OF THE DRAWINGS The first drawing shows a perspective view of a power generating apparatus which is constructed by applying the first embodiment of the present permanent magnet shielding apparatus. The second drawing shows a front view of a power generating apparatus which is constructed by applying the present embodiment of the permanent magnet shielding apparatus. The third figure shows a longitudinal sectional view of a power generating apparatus which is constructed by applying the first embodiment of the present permanent magnet shielding apparatus. The fourth figure shows the stereoscopic notation of the multilayer mask of the first embodiment of the present permanent magnet shielding device. Fig. 5 is a schematic perspective view showing the permanent magnet shield of the first embodiment of the permanent magnet shielding device of the present invention. The sixth figure shows a longitudinal sectional view of the first embodiment of the permanent magnet shielding device in the present power generating apparatus after the addition of the magnetic sleeve. The seventh drawing shows a schematic diagram of the magnetic field distribution of the first embodiment of the present permanent magnet shielding device. Fig. 8 is a longitudinal sectional view showing the first embodiment of the permanent magnet shielding device in the present power generating apparatus, after the electromagnetic generating module is incorporated. The ninth figure shows a magnetic field distribution diagram of the first embodiment of the permanent magnet shielding device of the present invention added to the electromagnetic generating module m-35-201203806. The second embodiment of the permanent magnet shielding device of the present invention is used to form a perspective view of a power generating apparatus. The drawing system does not apply the second embodiment of the present permanent magnet device to form a front view of the power generating device. $12 图图 shows the second embodiment of the permanent magnet shielding device of the present invention. The longitudinal section of the magnetic sleeve and the electromagnetic generating module is added. Fig. 12 is a perspective view showing the permanent magnet shield of the second embodiment of the permanent magnet shielding device. Fig. 14 is a perspective view showing the construction of the power generating apparatus using the third embodiment of the present permanent magnet shielding apparatus. The fifteenth diagram is a longitudinal sectional view showing a configuration of a power generating device according to a third embodiment of the permanent magnet shielding device of the present invention. Fig. 16 is another perspective view showing the permanent magnet shield of the third embodiment of the permanent magnet shielding device of the present invention. Fig. 17 is another perspective view showing the permanent magnet shield of the third embodiment of the permanent magnet shielding device of the present invention. Fig. 18 is another perspective view showing the permanent magnet shield of the third embodiment of the permanent magnet shielding device of the present invention. -36· 201203806 The nineteenth diagram is a schematic diagram showing the magnetic field distribution of the permanent magnet of the third embodiment of the present invention in a free state. Fig. 20 is a view showing the distribution of the magnetic field after the cylindrical magnetic core is attached to the third embodiment of the permanent magnet shielding device of the present invention. The twenty-first drawing shows a longitudinal sectional view of the third embodiment of the permanent magnet shielding device in the present power generating apparatus after the electromagnetic generation module is added. The twenty-second figure shows a schematic diagram of the magnetic field distribution after the third embodiment of the permanent magnet shielding device of the present invention is added to the electromagnetic generating module. The twenty-third figure is a longitudinal sectional view showing the third embodiment of the permanent magnet shielding device in the present power generating apparatus after the addition of the magnetic conductive sleeve. The twenty-fourth embodiment is a perspective view showing a further improved multi-layered mask of the third embodiment of the permanent magnet shielding device of the present invention. The twenty-fifth figure shows a perspective view of a power generating apparatus which is constructed by applying the fourth embodiment of the present permanent magnet shielding apparatus. Fig. 26 is a longitudinal sectional view showing the fourth embodiment of the permanent magnet shielding device in the present power generating apparatus, after the magnetic conducting sleeve and the electromagnetic generating module are added. Figure 27 is a perspective view showing the permanent magnet shield of the fourth embodiment of the permanent magnet shielding device of the present invention. The twenty-eighth figure shows the magnetic field distribution of the fourth embodiment of the present permanent magnet shielding device

[SI -37- 201203806 Intent. Fig. 29 is a perspective view showing the shielding plate of the fourth embodiment of the permanent magnet shielding device of the present invention. Fig. 30 is a perspective view showing the cylindrical magnetic conductive wall of the fourth embodiment of the permanent magnet shielding device of the present invention. The thirty-first figure shows the magnetic field distribution of the fourth embodiment of the present permanent magnet shielding device. The thirty-second diagram shows the magnetic field distribution of the fourth embodiment of the present permanent magnet shielding device. The thirty-third figure is a longitudinal sectional view showing a further improvement of the fourth embodiment of the permanent magnet shielding device of the present invention. Figure 34 is a perspective view showing the permanent magnet shield of the fourth embodiment of the permanent magnet shielding device of the present invention. The thirty-fifth diagram is a perspective view showing a fifth embodiment of the permanent magnet shielding device of the present invention which constitutes a power generating apparatus. The thirty-sixth embodiment shows a longitudinal sectional view of a power generating apparatus which is constituted by the fifth embodiment of the permanent magnet shielding apparatus of the present invention. Figure 37 is a perspective view showing the permanent magnet shield of the fifth embodiment of the permanent magnet shielding device of the present invention.

[SI-38-201203806] The thirty-eighthth embodiment shows a longitudinal sectional view of a power generating apparatus which is further modified by the fifth embodiment of the present invention. The thirty-ninth drawing shows a perspective view of the permanent magnet shield of the fifth embodiment of the present invention. The fortieth diagram is a perspective view showing the further improvement of the permanent magnet shield of the fifth embodiment of the permanent magnet shielding device of the present invention.

The forty-first figure is a perspective view showing the multilayer mask of the fifth embodiment of the permanent magnet shielding device of the present invention. Fig. 42 is a longitudinal sectional view showing the fifth embodiment of the permanent magnet shielding device of the present creation power generating apparatus after the electromagnetic generation module is added. The forty-third figure is a schematic view showing the magnetic field distribution of the permanent magnet of the fifth embodiment of the present invention in a free state. The forty-fourth embodiment is a schematic view showing the magnetic field distribution of the fifth embodiment of the permanent magnet shielding device of the present invention in which the guide sleeve is attached. First Embodiment The fifteenth diagram shows the magnetic field distribution of the fifth embodiment of the permanent magnet shielding device of the present invention. The forty-sixth embodiment shows a perspective view of the first embodiment of the present invention. The forty-seventh drawing shows a front view of the first embodiment of the authoring drive apparatus. The forty-eighth drawing shows a front view of the second embodiment of the authoring drive apparatus. 201203806 The forty-ninth aspect shows a perspective view of the third embodiment of the authoring drive device. Fig. 50 is a longitudinal sectional view showing a third embodiment of the present invention. The fifties represent the third real complement of the creation of the crane equipment. The fifty-second figure is an image showing the third embodiment of the driving device of the present invention. Called the fifty-third figure is the table _ drive device third real _ reciprocating dynamic magnet linkage stereo view. The fifty-fourth embodiment shows a perspective view of the third embodiment of the present invention, in which the reciprocating magnet linkage and the sliding engagement cooperate with the first embodiment. The fifty-fifth implicit forest creation and replacement of the third embodiment of the nano-reaction magnet linkage frame and the slide rail cooperate with the second embodiment. • Fig. 56 shows a perspective view of the crank link of the third embodiment of the authoring drive apparatus. ^ The fifty-seventh figure shows the third implementation of the creation drive device. >,, the fifty-eighth _ indicates the third implementation of the __ device (four) shot _ stereoscopic diagram. The fifty-ninth meaning table forest _ power generation read another - implementation of the three-dimensional view. 201203806 The sixtyth diagram is a longitudinal sectional view showing another embodiment of the present power generating apparatus. Figure 61 is a perspective view showing the disk-shaped permanent magnet in the embodiment. Figure 62 is a perspective view showing the rotating shielding module in the embodiment.

11 frame; 25 rotary joint 12 central fixed shaft; 26 bearing 13 annular permanent magnet; 27 power input wheel 14 rotating shield module ·, 28 power generating coil 15 rotating joint; 29 magnetic sleeve 16 sleeve; 210 contact Surface 17 power input wheel; 211 electromagnetic generation module 18 power generation coil; 212 positioning collar 116 矽 steel sheet; 213 shielding body 19 magnetic sleeve; 31 frame 110 contact surface; 311 left bracket plate 111 electromagnetic generation module; Right bracket plate 112 positioning collar; 34 support member 113 magnetic field line; 341 left half shaft 201203806

114 magnetic line; 342 115 shielding body 21; 343 22 central fixed shaft; 32 23 annular permanent magnet; 33 24 rotating shielding module; 321 323 butterfly end body 411 324 power input wheel 412 325 bridging side wall body 413 326, 327 Butterfly end face body 414 328 Bridge side wall body 415 329 Lower butterfly end face body 416 330 Curved edge 418 331 Curved plate 421 332 Curved edge 422 333 Upper butterfly end face body 424 341, 343 Left and right half shaft 425 Guide Magnetic core right half shaft rotation shielding module disc permanent magnet 322 Rotary joint power input wheel magnetic gap magnetic permeability magnetic line induction power generation equipment silicon steel magnetic sleeve electromagnetic generation module positioning collar circular magnetic side magnetic wall main body [S] -42- 201203806

344 Electromagnetic generation module 426 Center line 346 Magnetic sleeve 405 Rotary shielding module 35 Power generating equipment 406 Bridging ribs 41 Rack 51 Rack 42 Center fixed shaft 52 Center fixed shaft 43 Permanent magnet 53 Disc permanent magnet 44, 45 Plate type rotating shielding module 54 Half-shell fixed shielding body 46 Bridging rib 55 Rotating shielding module 47 Rotating connecting piece 56 Rotating connecting piece 48 Cylindrical magnetic conductive wall 503 Induction power generating device 49 Support frame 508 Pneumatic bearing 410 Limit bearing 419 Contact surface 420 magnetic line 423 magnetic line 509 pneumatic bearing body 1010 permanent magnet 5106 sector 1011 semi-circular permanent magnet 511 fixed column 1012 magnet block 512, 513 bracket plate 1013 crank linkage m -43- 201203806

514 bracket plate 1014 rotating shaft 515 fastening parts 1015 frame 530 electromagnetic generation module 1016 power output wheel 540 magnetic sleeve 1017 flywheel 541 circular end face 2003 left linkage frame 542 cylindrical side wall 2004 right linkage frame 551 butterfly end face 2005 Guide post 552 Curved side wall 2006 Rack top cover 57 Power input pulley 2007 Permanent magnet shield 1001 Rack 2008 Center fixed shaft 1002 Fixed platform 2009 Power input wheel 1003 Left linkage frame 2010 Ring permanent magnet 1004 Right linkage frame 2011 Semicircle Permanent magnet 1005 Guide post 2012 Guide magnet block 1006 Rack top cover 2013 Crank linkage mechanism 1007 Permanent magnet shielding device 2014 Rotary shaft 1008 Center fixed shaft 2015 Rack 201203806

1009 power input wheel 2016 power output wheel 3001 frame 3023 linear bearing 3002 support frame 3024 strip slide 3003 center fixed shaft 3025 sliding support sleeve 3004 disc permanent magnet 3026 strip chute 3005 rotating shielding module 3027 sliding support rail 3006 N-pole butterfly shielding plate 3028 from synchronous wheel 3007 S-pole butterfly shielding plate 3029 synchronous toothed belt 3008 bridged magnetic plate 3030 crank 3009 rotating connector 3031 connecting rod 3010 reciprocating moving magnet linkage 3032 from synchronous wheel 3011 crank connecting Rod mechanism 3033 Synchronous toothed belt 3012 Power output shaft 3034 Magnet linkage 3013 Power output wheel 3035 Magnet 3014 Flywheel mechanism 3036 Working surface 3015 Fixing plate 3037 Working surface 3016 Moving magnet m -45- 201203806 3017 Magnetic sleeve 3018 Magnetic Gap 3019 Electromagnetic generation module 3020 Bearing 3021 Cylindrical rail 3022 Support sleeve

Claims (1)

201203806 VII. Patent application scope: The type of drive includes a wheel and a __ permanent magnet ore device, a permanent magnet body cover #匕 帛 帛 permanent magnet connection sleeve, the aforementioned first-rotor shielding module around the permanent magnet, the power input module 'the aforementioned power input The module can drive the miscellaneous shielding module to rotate relative to the first permanent magnet; the rotating shielding module is provided with at least one notch for passing the first permanent magnet=force line; and (4) the driving system further comprises at least one relative The moving member of the slanting movement of the above-mentioned branch frame, the control device for controlling the rotation of the ship, and the driving control device for the county, and at least one power output device for outputting the mechanical energy of the moving piece; the first water magnet N pole and the 8 The poles are each provided with at least one and a permanent magnet polar phase _ two permanent magnets; wherein the first permanent magnet and the second permanent magnet are disposed on the moving member and the other is disposed on the frame. The power output device is further provided with the rotating shaft, and the driving system described in the first item is a rotating shaft. The rotating shaft is provided with a power output wheel flywheel. [3] The driving system according to the item i of the patent scope, wherein the rotating shielding die comprises a first shielding member and a second shielding member disposed in parallel with the first permanent magnet hard-to-pole surface and the S-pole surface. The distance from the first permanent magnet N-pole surface and the second shield member to the pole surface of the first permanent magnet 8 is the same, and the distance is 〇1~imm. 4. The driving system according to claim j, wherein the first permanent magnet is an axially magnetized disk-shaped permanent magnet, and the permanent magnet shielding device further comprises a first permanent magnet. In the magnetic module, the magnetic conductive module penetrates the first permanent magnet n and s pole faces, and the rotating shielding module is magnetically connected to the magnetic conductive module. The driving system of claim i, wherein the permanent magnet shielding device further comprises an electromagnetic generating module controlled by the foregoing control device, and the magnetic lines generated by the front AA 7X energization state can enter the rotating shielding. Inside the module. The drive system according to claim 5, wherein the magnetic pole of the electromagnetic generating module that generates a magnetic field in an energized state is in the same direction as the magnetic pole of the permanent magnet. 7. The driving system according to claim 5, wherein the rotating shielding module comprises a first shielding member and a second shielding member, wherein the electromagnetic generating module cooperates with the permanent magnet to cause the first shielding member and the first shielding member Two shields to magnetic saturation. 8. The drive system of claim 5, wherein the electromagnetic generation module comprises an electromagnetic generation module that loads an input current, the input current being an intermittent current. 9. The driving system of claim i, wherein the rotating shielding module comprises a first shielding member and a second shielding member, wherein the thickness of the first shielding member and the second shielding member are both 0.5 to 20 mm. between. The driving system of claim 1, wherein the rotating shielding module comprises a first shielding member and a second shielding member, wherein the first shielding member and the second shielding member are laminated by a plurality of magnetic conductive bodies. Composition. The driving system according to the first aspect of the invention, wherein the rotating shielding includes a first __rotation shielding module and a second rotating shielding module, and the first shielding member and the first shielding member are connected to form Multiple magnetic paths. 12. The root shot asks for the patent lang item 7 or item 9 or item 1() or the syllabus referred to in item u. == The masking member and the second shielding member are respectively associated with the permanent magnet: The drive system of claim 1, wherein the moving member is a moving rod and a front material. The first linkage rod is provided with at least one rsi -48 - 201203806 second magnetic shielding device between the second permanent magnets on the _-joint-linking rod. 15. The drive system includes a frame and a permanent shielding device, and the permanent shielding device includes a first permanent magnet, and the coupling module is disposed on the periphery of the first permanent magnet, and the power input module The power input module can drive the rotating shielding contact to rotate relative to the first permanent magnet; the rotating shielding mode has at least one front: the hydromagnetic magnetic line penetrates the notch; and the driving 1 thief includes at least __ The movable member provided by the movable mechanism, the drive-controlled weaving, and at least one of the aforementioned movements; the mechanical power of the female body; the aforementioned permanent magnet N-pole and __ each provided at least one of the magnets; One of the permanent magnet and the aforementioned magnetizer is disposed on the foregoing, and the other is disposed on the aforementioned frame. The foregoing power output is further provided on the rotating shaft. The driving system device according to the item _ _ 15 includes a turn _, the front miscellaneous _ has a Yang force output wheel, and has a flywheel. The driving system according to Item 15, wherein the rotating shielding mode is respectively arranged in parallel with the first permanent hybrid N-pole surface and the s-polar surface. The first-peripheral distance is the same as the first-permanent Zhao miscellaneous surface and the second second avoidance ΐ4, the first-subtractive S-pole surface distance is the same, and the distance is G^Cong. The body is! 1 ^ ^ Please __15 item Lai Zhi (4) system, the towel of the first permanent magnet: the shape of the body, the aforementioned Yong Gu ship I set also includes the magnetic module of the permanent magnet body, the aforementioned magnetic mode The set penetrates the first permanent magnet N and s pole faces, and the rotating shielding module is magnetically connected to the magnetic conductive module. The second shielding member of the thick household, the first shielding member and the second shielding member are entangled between 0_5 and 20 mm. 20. The drive system according to the fifteenth item, wherein the aforementioned rotation shielding i S ] 49. 201203806 The module comprises a first shielding member and a second shielding member 'the aforementioned first shielding member and the second shielding member The driving system of claim 20, wherein the rotating shielding module comprises a first rotating shielding module and a second rotating shielding module, the aforementioned first shielding member and The second shielding member is connected to form a plurality of magnetic conductive paths. Then, according to the driving system described in claim 19 or 2 or 2i, the first shielding member and the second shielding Pieces and permanent magnet N pole face and $ pole face flat