JP5330613B1 - A generator motor that connects several units using a storage battery. - Google Patents

Abstract

[PROBLEMS] To expand the inverter frequency rotation range of a generator motor, increase the electromotive force, and use the functions of the generator motor.
A generator motor provided with a strong magnetic rotor expands the inverter frequency range and at the same time pushes the rotor out of the stator yoke, so that the generator motor is used from low speed rotation to high speed rotation. The other generator motors that are driven by rotating the generator motor are functions of the generator motor that are added one after another by the generated electromotive force. From the generator motor output terminal to the rectifier, storage battery, booster, and inverter to the generator motor input line. And the electromotive force are circulated in turn and consumed by the input line rotary excitation coil, the electromotive force output from the power generation coil is used as the circulating electromotive force, and the infinite power of the generator motor using the storage battery is made possible, and the rotational force of the rotating shaft is the remaining power Use.
[Selection] Figure 4

Description

  The present invention relates to a power motor and a generator.

  The power generation motor is divided into a rotary excitation coil and a power generation coil, and the power generation motor is a motor having both power and power generation function. It can operate the driving force and power generation at the same time, and the power generation motor rotates with less power consumption at a certain inverter frequency. The generated electromotive force was output at a high voltage.

Patent No. 4571708 Patent No. 4951099 Patent No. 5150019

  The problem to be solved is that the output frequency range of the inverter driven to rotate the generator motor rotates only with a constant frequency with less power consumption, and the output excitation generated in the generator coil when the electromotive force is output to the load side is the rotation of the rotor. The power consumption of the generator motor was increased.

  In the present invention, a generator motor that has an inverter three-phase output 200V input to the input motor of the generator motor and that simultaneously executes rotational drive and power generation is specified with the rotor at a fixed position and the rotational speed and electromotive force. Fixed on the stator yoke of the generator motor, which can be selected to make the generator motor rotate, or to move the rotor from a fixed position and rotate the generator motor with low power consumption from low speed rotation to high speed rotation. The odd number of the coil is the input line rotation excitation coil and the even number is the power generation coil, or the odd number of the power generation motor is the input line rotation excitation coil and the even number is the same location number coil. For the same location number coil, the outer coil may be a power generation coil and the inner coil may be a serial wiring output line coil, or the outer coil may be a serial wiring output line coil and the inner coil may be a power generation coil. To make the same location number coil as a power generation coil, the crossover copper wire of the serial wiring output line coil is cut, and each homologous location number coil as the outer power generation coil and the inner power generation coil is set as the left output line and the right output line, It was set as the single phase power generation coil which used the output wire of the same direction of the same number as parallel wiring. Series wiring of power generation motor input line rotation excitation coil and same location number coil Output line coil and power generation coil should have the same number of turns as the input line rotation excitation coil turns, or slightly less coil turns, or half When the load of the electromotive force generated by the series wiring output line coil and the power generation coil is output, the coils are arranged so as not to impede the rotation of the rotor by lowering the output excitation of each coil. The electromotive force of the series wiring output line of the coil with the same location number as the input line rotation excitation coil of the additional generator motor is used as a power source for rotating the additional generator motor, and the rotation axis of the additional generator motor is connected by a timing belt for synchronous rotation. . Or, in order to increase the odd number of the generator motor with the input line rotation exciting coil and the even number with the generator coil, a three-phase wire is arranged in the input line rotation exciting coil of the generator motor, and the input lines in order from the first generator motor. The electromotive force of the additional generator coil, which is connected from the rotary excitation coil to the input line rotary excitation coil with a three-phase electric wire and connected to the rotating shaft with a timing belt, is synchronized with the rotation. The direct current that has been output and the output of the storage battery as a normal charging state is converted into a voltage and used in an inverter. The generator motors should be arranged in a horizontal row, or two units can be connected as a set, or the three units can be connected in a triangle, and each unit can be arranged in a triangle and concentrated on the center of the triangle with a belt. The additional rotational force is used as surplus power. The inverter output frequency range of the generator motor is expanded on the rotary shaft of the rotor used in the generator motor, and on the rotary shaft on which the air cooling fan inside the generator motor is arranged on the front cover side of the rotary shaft, the permanent magnet rotor, electromagnet A rotor, a magnet-inserted iron core rotor, a center-holed fan-shaped magnet rotor, an iron core rotor, and a squirrel-cage iron core rotor were used as the rotating shaft rotor of the power generation motor. When a three-phase 200V power is applied to a generator motor having a central perforated fan-shaped magnet rotor, the power consumption is within 2 amperes from 10 Hz to 60 Hz with no load rotation, and when the frequency is increased to 70 Hz, the power consumption is 15 In order to reduce power consumption to 2 amperes, the amperage consumption was reduced to 2 amperes by pulling out the rotor from the stator yoke by about 15 mm or pushing the rotor out. The higher the speed, the more the rotor is pulled out of the stator yoke, and the generator motor is driven to rotate from low speed to high speed with low power consumption.

The output collective terminal block wiring of the generator coil is the same as the terminal block output connection method of the generator coil for the two-pole generator motor, four-pole generator motor and six-pole generator motor, and the outer coil of the same location number coil as the generator coil is generated. The number of coil turns with the coil and the inner coil as the series wiring output line coil may be the same number of turns as the input line rotation excitation coil turns, or a slightly smaller number of turns, or a coil with half the number of turns. did. The three-phase power generator coil has the same location number coil or generator coil, two-pole generator motor outputs UVW No. 1 coil terminal block output, UVW each No. 2 coil terminal block output, and 4-pole generator motor has UVW No. 2 coil terminal block output Output, UVW each 4th coil terminal block output, 6-pole motor is a UVW each 2nd coil terminal block output, UVW each 4th coil terminal block output, UVW each 6th coil terminal block output, each generating coil In the single-phase power generation coil, the left and right copper wires are used as the right and left output lines for single-phase output at each terminal block, or three three-phase UVW output lines in the same direction are bundled as a neutral point and opposite Set the three-phase output wires in the side direction to star connection output at each terminal block, or gather the terminal blocks with each terminal block star connection into one place to obtain the aggregate terminal block star connection output, or collective terminal block star connection Remove the neutral point of the Was a delta output the data connection. Rectification can be achieved with a small number of rectifiers in the way of the collective terminal block output. A rectifier placed on the three-phase delta output terminal block or a fixed rectifier on the side of the fixed base slightly away from the generator motor, and the UVW output line is extended from the UVW collective terminal block delta output and coupled to the AC connection terminal of the rectifier The rectifier that is converted into direct current through the alternating current to the rectifier is either a three-phase rectifier or a single-phase rectifier. The single-phase rectifier uses three rectifiers and connects two rectifier AC input lines to three delta output terminals. It is assumed that the delta output terminals output evenly. By converting the alternating current into direct current and flowing a direct current higher than the storage battery charge voltage, the storage battery and the converter are charged while maintaining the state of charge, and the storage battery is rapidly using lithium ion storage battery, lead storage battery, electric double layer capacitor The storage battery is a mixture of charging and normal charging, and the direct current from the storage battery is converted to a voltage that matches the DC-DC or DC-AC 100V, 200V, 300V, or 400V device using an inverter or DC converter, and the booster A part of the electromotive force converted in step 1 is the power consumption on the load side. DC300V or AC200V was used as the DC connection terminal of the AC inverter or the inverter AC input line power source rotating the generator motor. The output of the three-phase inverter is input to the input motor of the generator motor, and the generator motor rotates and generates power, and the electromotive force is converted from the rectifier to the storage battery, booster, inverter and input. The electromotive force that was flowed in sequence with the wire rotation excitation coil and returned to the power generation motor was used as the circulating electromotive force, enabling infinite power of the power generation motor using a storage battery.

Lastly, add the odd number of the generator motor to the input line rotary excitation coil and the even number to the generator coil, and the odd number of the generator motor to the input line rotary excitation coil and the even number coil to the same location number coil. Expansion of the generator coil with the same number coil at the tail generator motor with the outer coil and inner coil in parallel wiring. To increase the number of generator motors, the number of poles of the generator motor is the same. The number of power generation motors arranged in the same direction as the number of coils and the number of winding motors are arranged. The number of turns of the input wire rotation exciting coil is the same as the number of turns, or the number of turns of the coil is half, the number of turns of the coil is half, and the star connection of the serial wiring output line coil as the same location number coil, or For the delta connection, the generator motor to be installed is the input line rotation excitation left-handed coil star or delta connection, the outer coil of the same location number coil is the generator coil, and the inner coil is connected in series. For the extension of the left-handed coil star or delta connection, connect the three-phase wire attached to the UVW three-phase series wiring output line of the first generator motor to the delta connection part of the 200v input line rotary excitation coil of the second generator motor. Connect the three-phase wire attached to the UVW three-phase series wiring output line of the No. 2 generator motor to the delta connection part of the 200v input line rotary excitation coil of the No. 3 generator motor, and manually rotate the rotary shaft of the No. 1 generator motor Since there is a position where the two units lightly rotate in the same direction at the same time as the rotation, if the inverter output is input to the input coil rotation excitation coil of the No. 1 generator motor at that position, the rotation axis position of the generator motor will deviate and will not rotate synchronously In order to prevent the rotation shaft position from deviating from three units, the three units are rotated synchronously in the same direction with the timing belt, gear, pulley, V-belt and flange. Alternatively, if the three-phase output line of the inverter attached to the No. 1 generator motor is removed and the pulley and belt attached to the rotation shaft of the No. 3 generator motor are rotated by the engine power, the power motor, and the power of the generator motor, the No. 2 generator motor The timing belt that synchronizes the No. 1 generator motor can be rotated without requiring a timing belt. When an electromotive force is input from a generator motor having a large number of coil turns to a generator motor having a small number of coil turns, the number of coil turns The rotation of the power generation motor with a large number of coil windings follows the rotation of the power generation motor with a large amount of rotation, and the rotation does not require a timing belt. The fixed coil of the generator motor is an input line rotary excitation coil and generator coil, and the three-phase wires are connected in order by connecting the input line rotary excitation coil of multiple generator motors to the input line rotary excitation coil as a star or delta. A rotating shaft that can be connected to the rotating shaft and attached to a rotating shaft with a gear, pulley, V-belt, timing belt, and flange, and the rotating position of a plurality of rotating shafts can be rotated in synchronization. The single-phase generator coil of the additional generator motor, which is designed to hang the pulley and pulley belt and rotate with the rotating shaft pulley of the engine power, power motor, and generator motor, is delta-connected or star-connected with the three-phase output terminal block Low voltage electromotive force output, connection part of series wiring output line and input line rotation excitation, or connection part of input line rotation excitation and input line rotation excitation From square of wire connecting portions to the electromotive force of high voltage output, and a plurality of intensifying conductive by merging a plurality minutes after the DC with a rectifier three-phase output terminal board output of the generator motor that is added. The input line rotation excitation coil and the series wiring output line of the strong magnetic rotor of the power generation motor are delta connection, and the input line rotation excitation coil and the series wiring output line of the weak magnetic rotor are star connection, from the generation motor strong magnetic rotor to the strong magnetic rotor. Or an extension from a strong magnetic rotor to a weak magnetic rotor, and a combination of a generator motor magnet rotor and a generator motor iron core rotor that does not require a timing belt. When the weak magnetic rotor is described as a fan-type magnet rotor with a central hole, the number of rotors covered by the fan with a central hole is less than half of the slot length.

The generator motor with a strong magnetic rotor is expanded in the inverter frequency range, the generator motor is rotated at high speed with less power consumption, and the rotor is housed in the stator yoke. The generator motor, in which the number is fixed and the electromotive force is constant, and the rotor of the generator motor moves in parallel, can expand the frequency range from low speed rotation to high speed rotation. Move the stator yoke from the fixed position to the rear lid side or the front lid side, and fix the stator yoke to the motor case at the position that matches either the required number of rotations or power generation voltage of the generator motor, and put the rotor out The arrangement in which the rotor is moved in parallel with the rotating shaft and out of the stator yoke is arranged by sliding the outer peripheral side of the left and right bearings of the rotating shaft inside the bearing case, and moving the entire rotor from the stator yoke. The bearing case for taking out the rotor was a bearing case having the same length as the moving distance in the parallel movement direction. Or, if the rotor is translated on the rotating shaft, the rotating shaft front cover bearing is fixed, the rear cover bearing case is a bearing case with the same length as the parallel moving distance, and the bearing case is penetrated to the outside of the rear cover. Bearing case. The bearing push pipe with the same diameter as the bearing is inserted into the bearing case from the outside of the rear lid. The length of the bearing push pipe is the length of the parallel movement distance, and a lid that is slightly larger than the pipe diameter is arranged outside the bearing push pipe. On the outer peripheral side of the lid used as a push pipe lid, a lid with a cut-in part that contains a detent material is used as a bearing push pipe lid with a hole for passing a push bolt or a tapped hole in the center of the lid. A nut was welded on the inside to reinforce the lid thread. A large pipe was put on the bearing push pipe lid, and a push bolt hole was made in the center of the lid, which was covered with the same circular lid, and fixed to the outside of the rear lid as a bolt pedestal pipe lid. Push the bolt from the outside into the bolt hole of the bolt cradle pipe lid, weld and fix the rotational force escape prevention plate to the bolt inside the lid with the bolt cradle pipe lid sandwiched between the bolt head and come out of the bolt cradle pipe lid When the bolt head is turned counterclockwise, the push bearing is pushed and the rotor is pushed out of the stator yoke and turned right. When the bolt head is turned right, it returns to a fixed position, or the push bolt is removed and the bearing push pipe lid and the bolt pedestal pipe lid inside, the bottom of the hydraulic cylinder The oil pressure is used to push the bearing push pipe lid, the rotor is moved in parallel, and the hydraulic pump is driven by the rotation of the rotating shaft or the electric pump that rotates the pump with electricity is used. Is equipped with an operation lever and provides a lever position for the push side, neutral, return side, and push and return operations of the hydraulic cylinder. It was parallel movement of the rotor Te. It is necessary to increase the inverter frequency along with the parallel movement of the rotor.To increase the frequency, a linear gear is arranged on the side of the bolt cover of the bolt or the hydraulic cylinder, and the upper pipe of the linear gear is connected to the length of the linear gear. Remove the moving measuring gear attached to the lid of the bearing push pipe lid from the cut out portion, combine the teeth with the linear gear, connect the spring interlocking material attached to the moving measuring gear to the inverter volume dial, and the bearing push pipe When moving in parallel, the moving measurement gear rotates, the interlocking material spring and dial rotate, the inverter frequency changes, and the generator motor rotates at high speed with low power consumption.

Machining of metal fittings and parallel moving materials arranged on the rotating shafts of the center-perforated fan-shaped magnet rotor, electromagnet rotor, and magnet-inserted iron core rotor with the rotating shaft rotor mounted on the generator motor in parallel movement is a restraint. The preventive material and the power transmission plate material are combined to form a T type, and the groove in which the thickness of the power transmission plate of the T-type power transmission plate turning prevention material enters is a power transmission groove. The groove is a groove whose length is the distance to be translated from the fixed position of the rotor. The groove is a groove with the number of poles of the generator motor that is perpendicular to the center of the rotation axis. The T-type power transmission plate is turned upside down on the rotating shaft with the anti-turning material of the T-type power transmission plate facing in the same direction. A pipe divided into the number of magnetic poles between the number of poles and the number of poles is arranged on the rotating shaft with a length of 10 mm left and right from the length of the stator yoke. The power transmission plate and the split pipe are temporarily fixed and welded, and the fan with a fan fixed disk is placed on the rotating shaft as the front lid side. The contact with was temporarily fixed. Temporarily fixed welding fixed disk with fan is made of copper wire air-cooled fan, and there are other fixed through-bolt holes in the center holed fan-shaped magnet with the number of magnetic poles. Welded fixed disk with fan and T-shaped power transmission Temporarily fix the plate and the split pipe, make sure that the fixture is lightly translated on the rotating shaft, tap weld the entire fixture, and confirm the parallel movement again after welding. Insert a rotor-fixed disk into the T-type power transmission plate turn-up prevention material side through a number of central-hole fan-shaped magnets through the magnetic through-bolts. The rotor-fixed disk has a central through-hole fan-shaped magnet fixed through-bolt holes, T The lower part is made on the outer peripheral side of the disk where the anti-turning material for the power plate of the mold enters, and the tip of the anti-turning part is V-shaped as the anti-turning material for the T-type power transmission plate is put on the lower stage and out of the rotor fixed disk The V-shaped cut part, which was cut into a wide part at the tip and narrowed toward the inside, was bent at 90 degrees with the part protruding from the rotor fixed disk facing the rotating shaft, and the V-shaped tip was perforated. The rotor fixing disk was tapped at a location, or both were tapped and bolted to provide a T-type power transmission plate magnet press-up prevention material. The nut that was fixed to the entire rotor by tightening the nut to the bolt that was finally passed through the rotor fixing disk of the through bolt was fixed with resin-based glue. An internal air cooling fan for air cooling of the generator motor is disposed on the rotating shaft on the front lid side of the rotating shaft, and the fixing bracket material constituting the rotating shaft rotor may be a stainless material or a stainless material that reacts to a magnet slightly. It was. The stator yoke and rotor installed in the generator motor are placed at a fixed position on the rear lid side, the front lid bearing is fixed by the bearing case and the front lid, and the rotor is pushed by one or two bearings on the rear lid side. The bearing case length of the rotor push side bearing of the rear lid is the length of the parallel movement distance, and the bearing case is made to penetrate to the outside of the push side bearing case lid, and the outer periphery of the bearing is slid within the bearing case and inside the bearing. Push bearing that allows the rotating shaft to slide. A rotor push pipe is inserted into the rotary shaft between the translation rotor and the push bearing, and the inner diameter of the inserted pipe is an inner diameter that can be easily inserted into the rotary shaft by hand, and there is no gap between the rotary shaft and the rotary shaft. The push pipe was pushed by the rotary part on the rotary shaft side of the push bearing. Rotating shaft rotor parallel movement is a process of digging a groove to translate the rotor to the rotating shaft, or processing the rotating shaft into a parallel moving length to add a quadrangular prism, pentagonal column, hexagonal column, octagonal column and polygon. The length of the polygonal cylinder that has been processed into a polygonal column without machining directly on the rotating shaft is either parallel to the fixed position. A hole with a rotating shaft diameter is machined in the center of a polygonal parallel translation material that is the length of the moving length, and the rotational axis is press-fitted into the parallel translation material with a polygonal column hole to translate the rotational axis and the polygonal cylinder. A rotating electromagnet rotor that inserts into the rotating shaft, transmits power in the direction of rotation of the rotating shaft, and slides in parallel with the rotating shaft on the rotating shaft that prevents the material from slipping. An iron core rotor was used. The pushing pipe of the polygonal parallel translation material is a rotor pushing pipe in which the portion from the rear lid side rotor where the 10 mm polygonal parallel translation material is put into the pipe inner diameter to the push bearing is the length and inner diameter of the pipe. On the push bearing side of the pipe, a plain washer with a rotating shaft in the center or a ring is used as the push pipe lid, and protrusions are made on the rotating shaft side and the push bearing side of the lid. Push on the side rotating part and translate the rotor with the rotor push pipe.

The front / rear direction of the generator motor is the front lid side of the rotary shaft that transmits power, and the generator motor case is an angle leg that faces the front and rear sides of the generator motor case with a cylindrical side facing outward. A flat bar rib reinforcing plate is provided on the inner side of the plate, and a portion in contact with the motor case is used as a fixed base of the welded motor. A low-cooled air-cooled air jump ring is welded to the inside of the rear cover side of the generator motor case, and other bolt holed squares that secure the motor case and front and rear lids are evenly arranged on the outer circumference of the case front and rear. And the input terminal block and the output terminal block are arranged on the upper part of the hole, which is a motor case in which a hole for passing one or two input lines and output lines is made. It is assumed that a rubber edge insulation preventive material or a dust intrusion preventive material is provided to prevent dust from entering, wiring scratches, and electric leakage. The rear lid of the generator motor has two types of lids, and the same lid as the front lid is used as the rear lid, or the rear lid has a different bearing case arrangement from the front lid. The front lid has a lid outer diameter that is 3mm larger than the outer diameter of the motor case cylinder, and the edge of the motor case cylinder has an outer edge that turns the edge to the motor case from the outer diameter side inside the lid so that the center of the lid does not shift. The edge is machined with no gaps in the gap, and the front lid is welded and fixed at the part where the lid touches the edge. Squared holes with bolt holes are welded to the edge of the front lid. It was arranged in the same place as the square bar, and the lid and the motor case were fixed by passing bolts through the square hole in the lid edge and the square hole in the motor case. The inner edge of the lid edge and the outer periphery where the motor case enters are lathe processed, or the edge width from the inner side of the lid, which is not to be turned, is 10 mm to 50 mm and is increased depending on the diameter of the motor case. A bearing case that houses and fixes the rotary shaft bearing is provided around the center of the front lid where the front rotary shaft is inserted, and a reinforcing plate that reinforces the outer circumference of the bearing case is placed on the outer periphery of the bearing case. Evenly disposed and welded, the front cover of the power generation motor was formed with a hole in the air suction port between the reinforcing plate and the reinforcing plate. Filters are individually attached to the lid of the front lid from the outside, or the filter is put on the outside of the lid and a hole with a rotating shaft is inserted in the center. Cut the pipe in half and divide the pipe into a hole parallel to the lid and fix the pipe so that no air leaks. Make a buffer part in the middle of the pipe where the pipe is extended to a place where dust does not float, and place the magnet inside the buffer part to adsorb iron powder etc. It was used as a buffer part that sucked out water and kept moisture, heavy garbage, etc. The rear lid has the same structure as the front lid, or a rear lid with a structure that differs only by the arrangement of the bearing case. If the rear lid has the same structure as the front lid, both the front and rear lids have a rear lid that fixes the bearing with the lid material. Air outlet was used. The arrangement of the bearing case, which is different in structure from the front lid of the rear lid, is arranged so that the bearing case penetrates the rear lid and protrudes to the outside of the rear lid, and the outer side of the rotating shaft rear lid side slides inside the bearing case and rotates at the same time. The shaft is also machined without any gaps so that it slides inside the bearing. The length of the machined bearing case is the length of the parallel movement distance of the rotor plus one or two bearings. The inner diameter of the bearing case is turned. The hole in the rear lid was an air outlet or a hole for attaching an electric forced air discharge electric fan. In the thin plate stator yoke, when the thin plate is manufactured, the slot of the input line rotation exciting coil and the slot of the power generation coil are the same type, slightly smaller slots, or half the size of the stator yoke. The protrusions attached to both ends hold the front and back of the stator yoke in the stacking direction, and are further welded directly to the stator yoke through holes formed in the gap material to fix the gap material and the stator yoke. The stator yoke is fixed between the yokes, and the protrusion of the gap material is fixed to be welded to the inner side of the motor case. The gap material is fixed to the gap material with the thickness of the gap material as an air-cooled air passage. In a motor case in which the stator yoke is moved to a fixed position in the center of the motor case or a predetermined position on the rear lid side and the stator yoke is fixed by the motor case, the suction port on the inner side of the front lid is connected to the entire air suction port from the outside. A truncated cone with a large truncated cone on the inner side is spread from the inside of the front lid diagonally inside the motor case and inserted under the internal air cooling fan inside the motor case to fix it. Arranged as a processed suction air direction indicator plate, it is a thin plate truncated cone that changes the direction of the air sucked by the internal air cooling fan attached to the rotating shaft to the rear lid side, and the air induction material is the gap on the front lid side of the stator yoke The thickness of the gap between the material projections is from the stator yoke side of the air passage to the middle position of the copper wire coming out of the slot of the fixed coil, or from the upper part of the copper wire to the stator yoke side of the gap material The pedestal is narrow on the copper wire side and is an air guide material fixed to the gap material projection as a wide truncated cone on the gap material side, and air is forced to enter the air passage of the gap material. Insulating materials such as polyurethane resin, asbestos, glass fiber, ceramics, acrylic, anti-leakage paint, and non-flammable insulating materials.

The distributed winding coil of the two-pole generator motor is arranged in the stator yoke with slots No. 1 to No. 24, the fixed coil is arranged as the same location number coil, and the coil number, the slot number, and the left and right direction are fixed coil lead copper wires The stator yoke side to be attached is the right and left direction when viewed from the rotation axis direction, the slot number and the coil number are clockwise, the slots are numbered 1 to 24, the number of turns of the input line rotation exciting coil and the number of turns of the generator coil are Three-phase UVW each having the same number of turns, a slightly smaller number of turns, or half the number of turns, the outer coil of the same location number coil as the power generation coil, and the inner coil as the input line rotation excitation coil No. coil is a left-handed coil, and each of the three-phase UVW second coils is a right-handed coil. The left-handed coil is placed in the slots 2 to 11 with the copper wire as the input wire, the winding end copper wire is the U1 neutral point, and the U2 wire input line rotational excitation second coil winding is started as the copper wire from the 23rd. The right-handed coil is placed in the 14th slot and the end copper wire is placed at the U2 neutral point. The U-line 1 generator coil is placed in the 1st and 12th slots, and the copper wire taken out from the 1st slot is placed in the U1. The left output line, the copper wire coming out of the 12th slot is the U1 right output line, the U-line No. 2 power generation coil is coiled in the 13th and 24th slots, and the copper wire coming out of the 13th slot is the U2 left The output wire, the copper wire coming out of the 24th slot is the U2 right output line, the V1 line input line rotational excitation 1st coil winding is started and the copper wire is the input line, and the left-handed coil is placed in the 10th to 19th slots. End copper wire to V1 neutral point, V2 wire input line rotation excitation Winding No. 2 coil with copper wire as input line, right-handed coil placed in slots No. 7 to No. 22, winding end copper wire at V2 neutral point, V-wire No. 1 generator coil in No. 9 and No. 20 slots The copper wire that is coiled out from the 9th slot is the left 1 output line, the copper wire that goes out from the 20th slot is the right 1 output line, and the V-line 2 generator coil is coiled in the 8th and 21st slots. Set the copper wire from the 8th slot as the right 2 output line, the copper wire from the 21st slot as the 2 left output wire, the W line input line rotational excitation 1 coil winding start and the copper wire as the input line 18th The left-handed coil is placed in the 3rd slot and the winding end copper wire is the W1 neutral point, the W-wire input line rotation excitation 2nd coil winding is started and the copper wire is the input line, and the right-handed coil is placed in the 6th to 15th slots. Set the winding end copper wire to the W2 neutral point, and the W wire No. 1 generator coil is No. 17. The coil placed in the No. 4 slot and the copper wire coming out of the No. 17 slot is the W1 left output line, the copper wire coming out of the No. 4 slot is the W1 right output line, and the W line No. 2 power generation coil is No. 5 and No. 16. The copper wire placed in the slot and extending from the 5th slot is the W left 2 output line, the copper wire coming out of the 16th slot is the W2 right output line, and all the coils are single phase power generation and the UVW is the same place Install in the No. 1 output terminal block and the UVW co-location No. 2 output terminal block, or bundle the three right and left copper wires of the single-phase generator coil of each three-phase terminal block in a bundle, and output in the opposite direction The wire is used as a star connection output, or the UVW of each star connection of the first output terminal block and the second output terminal block is assembled to provide one output line for U and U, V and V, and W and W. Set the star connection to a three-phase output terminal block, or remove the star-connected neutral point The neutral point was a three-phase delta output a delta connection in a total three-phase output terminal board. When a three-phase 200V input line rotational excitation coil is used as a rotational excitation coil with half the number of coil turns, three-phase 100V is input to the input line.

The same number coil is installed in the stator yoke in the slots 1 to 36 in the distributed winding coil of the 2-pole generator motor, and the generator coil is the same number of turns as the input line rotation exciting coil turns or slightly less coil The coil number, slot number, and left-right direction are the number of turns, or the coil number, slot number, and the left-right direction are the slot number and coil number, with the stator yoke side to which the fixed coil lead copper wire is attached as viewed from the rotation axis direction. Is the serial number in the clockwise direction, the slots are No. 1 to No. 36, the outer coil of the same location number coil is the generator coil, the inner coil is the input line rotation excitation coil, the three-phase input line rotation excitation No. 1 coil is the left-handed coil, and the three-phase Arrangement in which the second coil of the input line rotational excitation is a right-handed coil is arranged such that the first winding of the U1 line input line rotational excitation first coil starts with the copper wire as the input line from No. 2 to 17 No. 3 to No. 16 are provided with left-handed coils in slots No. 3 to No. 16, with the end of winding of the No. 16 slot being the U1 neutral point and the starting winding of the U2 line input line rotational excitation No. 2 coil as the input line. No. and No. 34 through No. 21 slots are provided with right-handed coils, and No. 21 slot winding end copper wire is placed at the U2 neutral point, and U1 generator coils are provided at No. 1 through No. 18 slots. The output copper wire is the U1 left output line, the copper wire output from the 18th slot is the U1 right output line, and the U2 power generation coil is coiled in the 19th to 36th slots and the copper wire output from the 19th slot is U2 left output line, copper wire coming out of slot 36 is U2 right output line, V1 input line rotation excitation No. 1 coil winding start copper wire is input line, 14th to 29th and 15th to 28th slots Left-handed coil 8th slot winding end copper wire is V1 neutral point, V2 input line rotational excitation 2nd coil winding start copper wire is input line, and right-handed coil is placed in each slot from 11th to 32th and 10th to 33rd The 33rd slot winding end copper wire is the V2 neutral point, the V1 generator coil is coiled in the 13th to 30th slots, the copper wire coming out of the 13th slot is the V1 left output line, the copper coming out of the 30th slot The V2 right output line is the V1 power output coil, and the V2 generator coil is placed in the 12th to 31st slots, the copper wire coming out of the 12th slot is the V2 right output line, the copper wire coming out of the 31st slot is the V2 left As the output line, the W1 line input line rotational excitation No. 1 coil winding start copper wire is the input line, and the left winding coil is arranged in each slot from No. 26 to No. 5 and No. 27 to No. 4, and the No. 4 winding end copper wire is W1 Neutral point, W2 input line Rotation excitation No. 2 coil winding start copper wire is input wire, right winding coil is placed in each slot No. 23 to No. 8 and No. 22 to No. 9 and the winding end copper wire coming out from No. 9 slot is W2 neutral point The W1 generator coil is coiled in slots No. 6 to No. 25, the copper wire coming out of the No. 6 slot is the W1 right output line, the copper wire coming out of the No. 25 slot is the W1 left output line, and the W2 generator coil is Coils are arranged in slots 7 to 24, the copper wire coming out of the 7th slot is the W2 left output line, the copper wire coming out of the 24th slot is the W2 right output line, Phase generators are arranged on the No. 1 generator coil terminal block and No. 2 generator coil terminal block, or three bundles with the same direction of the left and right output lines of the single-phase generator coil of each three-phase terminal block as neutral points The output wire in the opposite direction to the star connection at the terminal block. Or an output, or, was a delta connection remove the neutral point of a set three-phase output terminal block and star-connected three-phase terminal board delta output.

Distributed winding coils of a quadrupole generator motor are arranged on the stator yoke with slots 1 to 24. The coil number, slot number, and left and right directions are the stator yoke side to which the fixed coil lead copper wire is attached as viewed from the rotational axis direction. In the left-right direction, the slot number and coil number are clockwise, the slots are numbered 1 to 24, the odd number coil is the input line rotation excitation coil and the even number is the generation coil, and the generation coil is the input line rotation excitation coil The number of turns of the coil is the same as the number of turns of the coil, the number of turns is slightly less, or the arrangement of the coil is half the number of turns of the coil. The left-handed coil is placed in the 1st to 6th slots, and the copper wire at the end of the 6th slot is placed in the 13th to 18th slots of the 3rd coil. 8th slot winding end copper wire is U neutral point, U generator coil is 2nd and 4th coil 7th and 19th copper wire is U left output line and 12th and 24th slot The copper wire taken out from No. 1 was used as the U right output line. V-line input line rotational excitation No. 1 coil winding copper wire is input line, left winding coil is placed in slots No. 5 to 10 of No. 1 coil, and No. 10 slot winding end copper wire is No. 17 of No. 3 coil The left-handed coil is placed in the 22nd slot and the end of winding of the 22nd slot is the V neutral point. The V generator coil is the left of the 11th and 23rd slots of the 2nd and 4th coils. The right output line is the copper wire from the 16th and 4th slots as the output line. W wire input line rotational excitation 1st coil winding start copper wire is input line, left winding coil is placed in 9th to 14th slot, 14th slot winding end copper wire is 3rd coil 21th to 2nd slot The left-handed coil is installed at the end of the 2nd slot and the copper wire at the end of winding is the W neutral point. The W generator coil is the left-handed output wire of the 2nd and 4th coils. The copper wires coming out of the 20th and 8th slots were used as the W right output line. The power generation coils are all single-phase power generation and are arranged on the 2nd output terminal block and the 4th output terminal block, and the output lines in the same direction of the single-phase power generation coils of each three-phase terminal block are neutral points. Connect three wires in a bundle, output wires in opposite directions as star connection outputs, or set two terminal blocks with star connection output as a collective three-phase output terminal block with one star connection output Alternatively, the neutral point of the star connection of the collective three-phase terminal block was removed, and a delta connection was made to obtain a collective terminal block delta output. Also, if the coil and neutral point of the coil with the input line rotation excitation coil as a left-handed coil are changed, the neutral point is changed to the input line rotation excitation coil, and the input line of the input line rotation excitation coil is changed to the neutral point, The input line rotation excitation coil is a right-handed coil.

Distributed winding coils of a 4-pole generator motor are arranged in the stator yoke with slots 1 to 48. The coil number, the slot number, and the left and right direction are drawn from the fixed coil to the stator yoke side when viewed from the rotating shaft direction. Left and right direction, slot number and coil number are clockwise serial numbers, slots are numbered 1 to 48, the odd numbered coil of the fixed coil is an input line rotating excitation coil and left-handed coil, and the even numbered coil is the same place number The outer coil is a power generation coil, the inner coil is a left-handed coil, and a series wiring output line coil is used. The number of turns of the series wiring output line coil is the same as the number of turns of the input line rotation excitation coil, or a slightly smaller number of coil turns. Or coil arrangement with half the number of coil turns, the U wire input line rotation excitation No. 1 coil winding start copper wire as the input wire The left-handed coil is placed in slots No. 1 to 12, and No. 2 to No. 11, and the 11th slot winding end copper wire is placed in the No. 3 to No. 25 to 36 and No. 26 to No. 35 slots. The 35th slot winding end copper wire is the U neutral point, the U series wiring output line No. 2 coil winding starts, the copper wire is the output line, and the left winding coil is arranged in the 14th to 23rd slots and the 23rd slot winding end The left-handed coil is placed in the 38th to 47th slots of the 4th coil, and the copper wire at the end of the 47th slot winding is set to the U-position neutral point, and the 2nd and 4th coils of the U generator coil The copper wires coming out of the thirteenth and thirty-seventh slots were designated as the U left output line, and the copper wires coming out from the twenty-fourth and 48th slots were designated as the U right output line. V-line input line rotational excitation No. 1 coil winding copper wire is used as input line, left-handed coil is placed in each slot from No. 9 to No. 20 and No. 10 to No. 19 A left-handed coil is installed in each of the slots No. 33 to No. 44 and No. 34 to No. 43, and the winding end copper wire of the No. 43 slot is the V neutral point, and the V series wiring output line No. 2 coil winding start copper wire is the output line. The left-handed coil is placed in slots 22 through 31 and the copper wire ends in the 31st slot. The left-handed coil is placed in slots 46 through 7 of the 4th coil and the copper wire in the 7th slot is finished at the same location as V. Neutral point, copper wire coming out of slots 45 and 21 of V coil 2 and 4 of V generator coil is V left output line, copper wire coming out of slots 8 and 32 is V right output A line. W line input line rotational excitation No. 1 coil winding start copper wire is input line, left winding coil is placed in each slot of No. 17 to No. 28 and No. 18 to No. 27, and the end of No. 27 slot winding copper wire of No. 3 coil A left-handed coil is disposed in each of the slots No. 41 to No. 4 and No. 42 to No. 3, and the copper wire at the end of the No. 3 slot winding is the W neutral point, and the W series wiring output line No. 2 coil winding start copper wire is the output line. The left-handed coil is placed in the No. 39 slot and the 39th slot winding end copper wire is placed in the No. 6 to 15th slot of the No. 4 coil. As a characteristic point, the copper wire coming out of slots 5 and 29 of the second coil and the fourth coil of the W generator coil is the W left output line, and the copper wire coming out of the slots 16 and 40 is the W right output. A line. The three-phase series wiring output line coil is used as the power source for the generator motor with an additional generator motor. The crossover copper wire from the second coil to the fourth coil of each phase of the wiring coil is cut to form a power generating coil, and the outer coil and the inner coil are connected in parallel with copper wires in the same direction and used as a single phase power generating coil. The output wire terminal block was connected in the same way as the 24 slots of the distributed winding coil of the quadrupole motor. The input line rotation excitation coil and the series wiring output line coil are described as a left-handed coil. However, when current flows from each neutral point, the coil is a right-handed coil, and both the input line rotation excitation coil and the series wiring output line coil are When the neutral point is changed from the neutral point to the input line rotation exciting coil and the series wiring output line, the right-handed coil is obtained.

Distributed winding coils in which the first and third phases of the quadrupole motor are the same winding coils and the two phases are reverse winding coils are arranged in slots 1 to 48, and the odd numbers are the first and third phases of the input line rotation exciting coil. Whether the phase is a left-handed coil, the second phase is a right-handed coil, the even number is the same place number coil, and the same place number coil is the same number of turns as the input line rotational excitation coil turns or is a small number of turns The arrangement of the coil with the same number as the number of turns of the half winding, the outer coil as the power generation coil, the inner coil as the series wiring output line 1 phase and the 3 phase as the left winding coil, and the 2 phase as the right winding coil Input wire rotation excitation No. 1 coil winding copper wire is used as input wire, left-handed coil is placed in each slot from No. 1 to No. 12 and No. 2 to No. 11, and the 11th winding end copper wire starts from No. 25 of No. 3 coil 36 and 2 The left-handed coil is placed in the slot No. 35 to No. 35, and the copper wire at the end of the No. 35 slot winding is the U neutral point, the U series wiring output line No. 2 coil winding is the output line, and the left-hand winding is in the No. 14 to 23 slot The coil is installed, the end of the 23rd slot winding copper wire is placed in the left winding coil in the 38th to 47th slot of the 4th coil, and the end of the 47th slot winding copper wire is set to the U-position neutral point. No. 2 coil Nos. 13 and 24 slots, No. 4 coil Nos. 37 and 48 slots, copper wires coming out of Nos. 13 and 37 slots, U left output line, Nos. 24 and 48 slots The copper wire used was the U right output line. V-line input line rotational excitation No. 1 coil winding start copper wire as input line, right winding coil is placed in each slot of No. 16 to No. 5 and No. 15 to No. 6 A right-handed coil is installed in each of the slots No. 40 to No. 29 and No. 39 to No. 30, and the copper wire at the end of the No. 30 slot winding is the V neutral point, and the V series wiring output line No. 2 coil winding start copper wire is the output line. The right-handed coil is arranged in the 27th to 18th slots, and the 18th slot winding end copper wire is arranged. The right-handed coil is arranged in the 3rd to 42th slots of the 4th coil, and the 42nd slot winding end copper wire is V. Same position neutral point, 2nd coil 17th and 28th slots of V generator coil, 4th coil 41th and 4th slot, copper wire coming out of 17th and 41st slots V left output line , Copper wires from slots 28 and 4 It was the V right output line. W line input line rotational excitation No. 1 coil winding start copper wire is input line, left winding coil is placed in each slot of No. 9 to No. 20 and No. 10 to No. 19, and the end of No. 19 slot winding copper wire of No. 3 coil A left-handed coil is arranged in each of the slots No. 33 to No. 44 and No. 34 to No. 43, and the copper wire at the end of No. 43 slot winding is set to the W neutral point, and the W series wiring output line No. 2 coil winding start copper wire is set as the output line. The left-handed coil is placed in the No. 31 to No. 31 slots and the end of the No. 31 slot winding copper wire is placed in the No. 46 to No. 7 slot of the No. 4 coil. The W generator coil No. 2 and coils No. 21 and 32 slots, the No. 4 coil No. 45 and No. 8 slots, the copper wire coming out of the No. 21 and No. 45 slots, W left output line, No. 32 From slot 8 Line was used as a W right output line. 1 phase and 3 phase are left-handed coils and 2 phases are right-handed coils, but when current flows from each neutral point, 1-phase and 3 phases are right-handed coils and 2 phases are left-handed coils. Was changed to a neutral point, and the neutral point that was provided was changed to an input line rotating excitation coil, the 1-phase and 3-phase were right-handed coils and the 2-phase was a left-handed coil.

The 6-pole generator motor distributed winding coil is arranged in the stator yoke with slots 1 to 36. The coil number, slot number, and the left and right direction are drawn to the fixed coil and the stator yoke side where the copper wire is attached is viewed from the direction of the rotation axis. Left and right direction, slot number and coil number are clockwise serial numbers, slots are 1 to 36, odd number coils are left-handed coils with input line rotating excitation coils, even number coils are used as generator coils and winding coils are wound The number of coil turns is the same as the number of turns of the input line rotation excitation coil, or the number of turns of the coil is slightly less, or the number of coil turns is half. The left-handed coil is placed in the 1st to 6th slots using the wire as the input line, and the end of the 6th slot winding is placed in the 13th to 18th slots of the 3rd coil A left-handed coil is placed and the 18th slot winding end copper wire is placed in the 5th coil in the 25th to 30th slots. A left-handed coil is placed, the 30th slot winding end copper wire is the U neutral point, and the U generator coil is the 2nd. Coil, No. 4 coil and No. 6 coil, and the copper wires coming out of slots No. 7, 19 and 31 of each coil are left output lines, and copper wires coming out of No. 12, 24 and 36 slots Right output line. V-line input line rotational excitation No. 1 coil winding copper wire is input line, left-handed coil is placed in slots No. 5 to 10, and No. 10 slot winding end copper wire is No. 17 to No. 22 slots of No. 3 coil The left-handed coil is disposed on the left and the 22nd slot winding end copper wire is disposed on the 29th to 34th slots of the 5th coil, the left-handed coil is disposed on the 34th slot winding end and the copper wire is the V neutral point. No. 4, No. 4 and No. 6 coils, and the copper wires coming out of the slots No. 11, 23 and 35 of each coil are the left output wires, and the copper wires coming out of the No. 16, No. 28 and No. 4 slots. The line is the right output line. W line input line rotational excitation 1st coil winding start copper wire is input line, left winding coil is placed in 9th to 14th slot, 14th slot winding end copper wire is 21st to 26th slot of 3rd coil The left-handed coil is disposed on the left and the 26th slot winding end copper wire is placed in the 5th coil from the 33rd to the 2nd slots, the left-handing coil is placed, the second slot winding end copper wire is the W neutral point, and the W power generation coil is 2 No.4, No.4 and No.6 coils, and the copper wires coming out of the slots No.15, No.27 and No.3 of each coil are the left output lines, and the copper wires coming out of the No.20, No.32 and No.8 slots. The line was the right output line. The power generation coils are all single-phase power generation coils, and each UVW coil has the same number, and is divided into a second output terminal block, a fourth output terminal block, and a sixth output terminal block for single-phase power generation, or In the terminal block, the same direction of the left and right copper wires is bundled in a bundle and connected as a neutral point, and the opposite-direction output wire as each terminal block star connection output, or each three-phase terminal block star connection output The star connection of each terminal block was used as a single connection terminal block star connection output, or the neutral point of the star connection was removed, and the collection terminal block was used as a delta connection to obtain a three-phase terminal block delta connection output. When a current is passed from a neutral point where the input line rotation excitation coil is a left-handed coil, the coil turns right-handed, and the input line rotation excitation coil is changed to a neutral point. Change to a right-handed coil.

Distributed winding coils of a 6-pole motor are arranged on the stator yoke with slots 1 to 72. The coil number, the slot number, and the left and right directions are those of the stator yoke side to which the fixed coil lead copper wire is attached as viewed from the rotational axis direction. Left and right direction, slot number and coil number are clockwise serial numbers, slot numbers are 1 to 72, odd numbers are left-handed coils of the input line rotation excitation coil, even numbers are the same place number coils, and the same place number The number of coil turns should be the same as the number of turns of the input line rotation excitation coil, or a slightly smaller number of turns, or a half number of turns, the outer coil as the power generation coil and the inner coil as the series wiring output line The coil arrangement of the left-handed coil of the coil is that the U-line input line rotational excitation No. 1 coil winding starts with the copper wire as the input line, No. 1 to No. 12, and No. 2 to No. 1 The left-handed coil is arranged in each slot of the No. 11 and the 11-slot winding end copper wire is arranged, and the left-handed coil is arranged in each of the No. 25 to 36 and 26th to 35th slots of the No. 3 coil. A left-handed coil is placed in each of slots No. 49 to No. 60 and No. 50 to No. 59 of the No. 5 coil, the copper wire at the end of the 59 slot winding is set to the U neutral point, and the U series wiring output line starts to No. 2 coil winding copper wire Is the left-hand coil in the 14th to 23rd slots and the end-turned copper wire is placed in the 38th to 47th slot of the 4th coil. The left-handed coil is placed in the 62nd to 71st slots of the 6th coil, the copper wire at the end of the 71st slot winding is defined as a neutral point at the U location, the 2nd U coil, the 4th coil and the 6th coil 13th and copper wires out of the 37 th and 61 th of each slot and the left output line, right output line copper wires out of the 24 th and 48 th and 72 th of each slot in the. V-line input line rotational excitation No. 1 coil winding copper wire is used as input line, left-handed coil is placed in each slot of No. 9 to No. 20 and No. 10 to No. 19, and the 19-slot winding end copper wire is the 33 of No. 3 coil No. 44 and No. 34 to No. 43 slots are provided with left-handed coils, and 43-slot end copper wires are provided in No. 5 coils No. 57 to 68 and Nos. 58 to 67 slots are provided with left-handed coils. The copper wire coming out of the 67th slot is the V neutral point, the V series wiring output line is wound as the 2nd coil, the copper wire is the output line, and the left-handed coil is arranged in the 22nd to 31st slots and the 31st slot is wound. End copper wire is placed in the left-handed coil in the 46th to 55th slots of the 4th coil and the 55th slot winding end copper wire is placed in the left-handed coil in the 70th to 7th slots of the 6th coil and 7 slots Winding A copper wire is a neutral point at the same location as the V, and a copper output from the slots 21, 45, and 69 of the V coil, the 4th coil, and the 6th coil is the left output wire. , The copper wire from the 32, 56 and 8 slots is the right output line. W line input line rotational excitation No. 1 coil winding start copper wire is input line, left winding coil is placed in each slot of No. 17 to No. 28 and No. 18 to No. 27, and the end of No. 27 slot winding copper wire of No. 3 coil A left-handed coil is placed in each of the slots from No. 41 to No. 52 and No. 42 to No. 51, and the copper wire at the end of No. 51 slot winding is placed in a left-handed coil in the No. 65 to No. 4 and No. 66 to No. 3 slots. Winding the 3rd slot with the copper wire as the W neutral point, the W series wiring output line as the 2nd coil, the copper wire as the output line, and the left-handed coil in the 30th to 39th slots as the 39th slot The winding end copper wire is arranged in the left-handed coil in the 54th to 63rd slots of the 4th coil, and the 63rd slot winding end copper wire is arranged in the 6th to 15th slot of the 6th coil. Number slot The end copper wire is the neutral point at the same location as the W, and the left output wire is the copper wire taken out from the slots 29, 53 and 5 of the second coil, the fourth coil and the sixth coil of the W same location power generation coil. And the copper wire from the 40th, 64th and 16th slots is the right output line. The three-phase UVW coil of the series wiring output line of the generator motor is used as the power source for the additional generator motor, and when the power generator is not required and the last generator motor is not required to connect the serial wiring coil, Cut the copper wire and connect it to the output line of the same numbered output line in the same direction to make a single-phase output of each output terminal block. The method of the three-phase input line terminal block connection and the three-phase output line is 36 of the 6-pole power generation motor The output method is the same as the stator yoke type of the slot, and the input wire rotation excitation coil is a left-handed coil and the series wiring output line is a left-handed coil. The winding coil and the series wiring output line coil are arranged as a right-handed coil, the input line rotation excitation coil and the series wiring output line coil are changed to neutral points, and the neutral point that has been arranged is input line rotation excitation. Direct with coil It was coiled direction right-turn coil by changing the wiring output coil.

6-pole generator motor distributed winding coils are arranged in slots 1 to 72 with 1-phase and 3-phase left-handed coils and 2-phase right-handed coils. The stator yoke side to which the wire is attached is the left-right direction as viewed from the rotation axis direction, the coil number and the slot number are the clockwise serial numbers, the first coil to the sixth coil, the slots are the first to the 72nd, The even number coil is the same place number coil in the input line rotation excitation coil, and the same place number coil winding number is the same as the input line rotation excitation coil winding number, or a little less coil winding number, or half The outer coil is a power generation coil, the inner coil is a series wiring output line coil, and the series wiring output line coil is also one phase and three phases left. The arrangement in which the two-phase coil is a right-handed coil is arranged such that the first winding of the U-line input line rotational excitation No. 1 coil is used as the input line, and the left-handed coil is arranged in each of the No. 1 to No. 12 and No. 2 to No. 11 slots. The 11th slot winding end copper wire is placed in the left winding coil in each of the 25th to 36th and 26th to 35th slots of the 3rd coil, and the 35th slot winding end copper wire is connected to the 49th coil of the 5th coil. No. 14 and No. 50 to No. 59 are provided with left-handed coils in the slots No. 14 with the 59th slot winding end copper wire as the U neutral point and the U series wiring output line No. 2 coil winding starting copper wire as the output line. The left-handed coil is disposed in the 23rd slot, the 23rd end winding copper wire is disposed, and the lefthanded coil is disposed in the 38th to 47th slots of the 4th coil, and the 47th end winding copper wire is disposed in the 62th coil. No. 71 to No. The left-handed coil is placed in the slot and the end of winding of the 71st slot is placed at the neutral point of the U coil, the U generator coil is the 2nd coil's 13th and 24th slots, the 4th coil is the 37th and 48th slots, The 61th and 72nd slots of the 6th coil were used, the copper wires coming out of the 13th, 37th and 61th slots were the U left output lines, and the 24th, 48th and 72th slots were taken out. Copper wire is U right output line. V-line input line rotation excitation No. 1 coil winding copper wire is the input line and the right-handed coil is placed in each slot from No. 16 to No. 5 and No. 15 to No. 6, and the copper wire at the end of No. 6 slot winding is No. 5 coil No. 64 to 53 and 63 to 54 are provided with right-handed coils, and the 54th slot winding end copper wire is placed in each of the No. 40 to 29 and 39 to 30 slots of the No. 3 coil. A right-handed coil is installed, and the copper wire at the end of the 30th slot is the V neutral point, the V series wiring output line is the 2nd coil winding, the copper wire is the output line, and the right-handed coil is placed in the 27th to 18th slots. The 18th slot winding end copper wire is placed in the right winding coil in the 6th coil from the 3rd to 66th slot, and the 66th slot winding end copper wire is wound in the 4th coil from the 51st to the 42nd slot. No. 42 slot winding with coil The end copper wire is a neutral point at the same location as the V. The V generator coils are the 17th and 28th slots of the 2nd coil, the 41st and 52th slots of the 4th coil, the 65th and 4th coils of the 6th coil. Slots, the copper wires coming out of slots No. 17, 41 and 65 are V left output lines, and the copper wires coming out of slots No. 28, No. 52 and No. 4 are V right output lines. W line input line rotational excitation No. 1 coil winding start copper wire is input line, left winding coil is placed in each slot of No. 9 to No. 20 and No. 10 to No. 19, and the end of No. 19 slot winding copper wire of No. 3 coil A left-handed coil is provided in each slot from No. 33 to 44 and 34 to 43, and a copper wire at the end of No. 43 slot winding is provided in each slot from No. 57 to 68 and No. 58 to No. 67 of the No. 5 coil. No. 67 slot winding end copper wire is the W neutral point, W series wiring output line No. 2 coil winding start copper wire is the output line, left winding coil is arranged in slots No. 22 to No. 31 and the 31st slot winding end copper wire The left-handed coil is placed in the 46th to 55th slots of the 4th coil, and the end of the 55th slot is placed in the left-handed coil, and the left-handed coil is placed in the 70th to 7th slots of the 6th coil. The copper wire is in the same location as the W, and the W generator coil is the 21st and 32nd slots of the 2nd coil, the 45th and 56th slots of the 4th coil, and the 69th and 8th slots of the 6th coil. The copper wires coming out of the slots No. 21, 45 and 69 were designated as the W left output line, and the copper wires coming out of the No. 32, No. 56 and No. 8 slots were designated as the W right output line. 1 phase and 3 phases are described as left-handed coils and 2 phases are described as right-handed coils. However, when current flows from each neutral point, 1-phase and 3-phase are right-handed coils and 2 phases are left-handed coils. The input line rotation excitation coil was changed to the neutral point, and the neutral point that was provided was changed to the input line rotation excitation coil to obtain a coil winding direction opposite to the described coil winding direction.

The permanent magnet of the center holed fan type magnet is a neodymium magnet, the slot length of the stator yoke of the generator motor is 150 mm, the thickness of the center holed fan type magnet disposed in the rotor is 10 mm, and one of the rotor magnet poles The ratio of the number of magnetic poles arranged to 11 and 15 to 11 is the best ratio for the rotor center hole fan magnet and the 200V input rotary excitation coil, and the center hole fan type required for rotor manufacture. The number of magnets can be predicted, the height of the stator yoke radius is 75 mm, the height of the center hole fan-shaped magnet is 35 mm, the space to the center is 40 mm, the magnet height and the bottom of the magnet By arranging the ratio of the distance from the rotating shaft side to the center of the stator yoke to be 7: 8, the thickness of the rotating shaft can be predicted with the ratio having the best compatibility.

  When a three-phase inverter 200v is input to a generator motor that uses a centrally perforated fan-shaped magnet rotor with a good compatibility with the generator motor rotation excitation coil of the present invention, a clamp ammeter attached to the input line during no-load rotation is used. The measured power consumption is a fixed position where the rotary shaft rotor does not move in parallel when power consumption within 2 A is measured at an output frequency from 10 to 60 hz, and the inverter output when the rotary shaft rotor is taken out from the 50 mm stator yoke The generator motor rotated at a frequency of 80 hz with power consumption within 4 A. Instead of removing the rotor of the generator motor, insert a squirrel-cage iron rotor to rotate it, and attach a three-phase capacitor to the inner series wiring output line of the co-located coil, and an inverter to input to the three-phase input line rotary excitation coil The AC voltage of the three-phase output is 200V, the frequency is 90hz, the rotation speed is 2.8A and the electromotive force voltage is 30V, and the generator motor that rotates and generates power with the power consumption of 3A is 120hz. Was measured.

2-pole generator motor No. 1 to No. 24 slot, coil in the same location 2-pole generator motor No. 1 to 36 slot, rotary excitation coil and generator coil Four pole generator motor No. 1 to No. 24 slots, rotating excitation coil and generator coil 4 pole generator motor No. 1 to No. 48 slot, same position coil as rotating excitation coil 6-pole generator motor No. 1 to 36 slot, rotation excitation coil and generator coil 6-pole motor No.1 to No.72 slots, same position coil as rotating excitation coil Rotary axis translational member for central hole fan-shaped magnet rotor Central perforated fan magnet fixing member, power transmission plate and groove, cross-sectional view Front cover of generator motor Polygonal parallel translation member of rotation axis, sectional view The gap material of the generator motor case and the stator yoke, sectional view

  Arrangement of three 6-pole generator motors in a horizontal row, individual rotating excitation coils connected by pulleys and pulley belts are coils in the same winding direction, and the first generator motor is arranged as an inverter three-phase input motor. The same location power generation coil of the location coil is a three-phase delta output of single-phase power generation, and the same location series wiring output line coil is a first generator motor having a star connection of a rotating excitation coil and a same direction winding coil. The same location coil of the No. 2 generator motor has the same wiring as the No. 1 generator motor, and the No. 2 generator motor. The power generating coil of the same location coil of the No. 3 power generation motor and all the coils of the serial wiring output line coil were used as the same location power generation coil to be the No. 3 power generation motor. The three three-phase delta output lines are assembled and flowed through a rectifier to be converted into direct current and stored in the storage battery, and then 12V or 24V is converted into direct current or alternating current of 100V, 200V, 300V or 400V by a booster or inverter.

  The coil with the same location number as the input line rotation excitation coil of the 6-pole generator motor used as a strong magnetic rotor, the coil with the outer coil of the same location number coil as the power generation coil and the inner coil as the power generation coil are connected in parallel, In order to output a single-phase load to the three terminals of the three-phase terminal block, which is a delta output, two output lines are connected to each other to obtain an average output, and one single-phase output line is provided on the load side. On the other hand, four projectors were connected, and a total of 12 projectors were arranged. The clamp ammeter attached to the input line when the inverter 200V is input to the generator motor and rotates at a frequency of 55hz outputs the generated voltage of the generator motor indicated as power consumption 4.0A to each of the 12 projectors and outputs a 30V voltage. AC output was measured. The output load condition is the same as described above for the generator motor in which the input coil of the 6-pole power generation motor is the same coil as the input coil rotation excitation coil, the outer coil of the same coil is the power generation coil, and the inner coil is the series wiring output line. The power consumption of the clamp ammeter attached to the input line when rotating at a frequency of 55hz is displayed as 3.80A, the output is measured by 30V voltage, the generator motor rotor is removed, the iron core rotor, the car The type iron core rotor is installed in the generator motor and the output load conditions are the same as described above. The generator motor is rotated by inputting 200 V from the inverter, and the generator motor rotates at a power consumption of 2.8 A at a frequency of 120 hz. The three-phase capacitor is attached to the three-phase series wiring output line when 30V voltage is measured. If a three-phase capacitor is attached to the three-phase series wiring output line, the power consumption of the rotating excitation coil will be slightly reduced, and a capacitor may or may not be attached.

The power generator motor with the same number of poles is connected from a coil with a large number of coil turns to a coil with a small number of coil turns. The rotation without a timing belt is a combination of a strong magnetic rotor and a strong magnetic rotor. Or a combination of a strong magnetic rotor and a weak magnetic rotor. Alternatively, the rotation without timing belt with the same number of poles added is a combination of a strong magnetic rotor generator motor and an iron core rotor generator motor. Multiple units can be added to a generator motor with the same polarity and a strong magnetic rotor, and the input line rotation excitation coil and the input line rotation excitation coil can be connected with a three-phase wire, and the rotation axis can be synchronized with the timing belt. Any number of units can be used, and the rotational force of the rotating shaft can be used as a surplus force.

  Generator motor output collective generator using a power three-phase power supply. Electric or hybrid vehicles can be used for power storage even while being driven by one or two generator motors. A single unit can be used as power for factories and can be stored during use. An infinite power generation motor using a storage battery was used.

1 U input line 2 V input line 3 W input line 4 U neutral point 5 V neutral point 6 W neutral point 7 U power generation left output line 8 U power generation right output line 9 V power generation left output line 10 V power generation right output Line 11 W power generation left output line 12 W power generation right output line 13 Serial number of each phase 14 U Co-location series wiring output line 15 V Co-location series wiring output line 16 W Co-location series wiring output line 17 U In the same location Neutral point 18 Neutral point at V 19 Neutral point at W same point 20 Push bolt 21 Relief material for bolt rotational force fixed to the push bolt 22 Reinforcement nut 23 attached to the inside of the push pipe lid Push pipe lid 24 Push bolt or Hydraulic cylinder pipe pedestal 25 Push pipe detent plate 26 Linear gear 27 Movement measuring gear 28 Spring material 29 interlocked with inverter volume dial Bearing case 30 of parallel movement distance length One push bearing 31 Rotor push pipe 32 Rotor through bolt and rotor last fixing nut 33 Split pipe 34 for sliding the rotor Rotor fixing disk 35 T-type power transmission plate turning prevention V-shaped bending portion 36 T-type power transmission plate turning prevention and magnet holding portion 37 Center-perforated fan-shaped magnet 38 T-type power transmission plate and welded fixed disk 39 in which a divided pipe is fixed T-type power transmission plate Groove for receiving power transmission plate for preventing turning or groove for transmitting power 40 Center-perforated fan-shaped magnet T-type power transmission plate 42 including a magnet presser and a power transmission plate 42 Welded portion 43 of rotor member 44 Rotating shaft 44 Front lid 45 Air suction port 46 Edge welded to lid 47 Bearing case and case reinforcing plate 48 Lid Bolt hole square member welded to the edge of the motor and bolt hole square member on the motor case side 49 Hydraulic jack 50 Air discharge forced fan or air discharge port 51 Internal air cooling air passage 52 Polygonal cylinder parallel moving material 53 Electric motor internal air cooling fan 54 Air cooling air direction indicator plate 55 Lid cylinder rotor push pipe projection cover 56 Pushing washer bearing side rotating portion projection portion 57 Gap material and projection Section 58 Electric motor fixing bolt hole 59 Angle leg and reinforcing flat bar 60 Thin laminated material 61 Air induction material 62 Coil air cooling fan 63 welded to welding fixed disk 63 Air cooling air jumping plate

Claims (3)

(A) The generator motor is composed of an inverter, a hydraulic pump and a hydraulic cylinder or jack (49), a linear gear (26), a movement measuring gear (27), a push pipe and a cradle (24), a parallel moving rotor, and a central hole. Fan-shaped magnet (37), magnet rotor fixing bracket, parallel moving material, power transmission groove (39), electric fan (50), same location number coil, storage battery, suction air direction indicator (54), internal air cooling fan (53 ), Interlocking material spring (28), gap material (57), air induction material (61), rectifier, DC-AC booster, rotary shaft power transmission member, polygonal column (52), filter The power generation motor is a functioning power generation motor. The power generation motor simultaneously performs rotational driving and power generation with the output of the inverter three-phase 200V. The motor case of the power generation motor includes a hydraulic pump and a hydraulic cylinder (4 ), A linear gear (26), a movement measuring gear (27), a push pipe and a cradle (24), and an interlocking material spring (28) are arranged on the rear cover of the motor case, and the push pipe and the cradle (24) The cradle is fixed to the outside of the rear lid, and is arranged as a bolt cradle pipe lid. By loosening or tightening the push bolt, the rotor is moved in parallel with the push pipe, or the push bolt is removed and the hydraulic cylinder is removed. A straight gear (26) is arranged on the side surface of the bolt cradle pipe lid, which has been translated in (49), and a movement measuring gear (27) is arranged on the push pipe lid, and both gears are combined. When the push pipe lid is moved, the interlocking material spring (28) is rotated to rotate the inverter volume dial to change the frequency. The electric fan (50) is disposed on the rear lid, and the suction air direction indicator plate (54) ) Arranged on the inside of the lid, the filter is attached to the air suction port of the front lid, or the piping is extended to a place where there is no air dust, and the stator yoke consists of a rotating excitation coil and a power generation coil. And the same location number coil, a gap member (57), and an air guide member (61). The gap member (57) includes a stator yoke fixed by the gap member in the motor case and a gap member ( 57) and the gap member (57) as an air passage (51), and an air guide member (61) is disposed in the gap member projection, and the parallel moving rotor has both bearings for fixing the rotating shaft in the bearing case. Or parallel movement, or using only a rotor with a central perforated fan magnet (37), magnet rotor fixing bracket, parallel moving material, power transmission groove and rotary power transmission plate, using a polygonal column Translate only the rotor Then, the rotor of the generator motor is translated to the rear lid side or the front lid side with the rotor stored in the stator yoke, the stator yoke is fixed to the motor case, the rotor is translated, and the rotor is pulled out from the stator yoke. As a result, the rotation speed and the electromotive force of the generator motor can be reduced from low to high with low power consumption within the specified output frequency range of the inverter. Select from iron core rotor, electromagnet rotor, iron core rotor, squirrel-cage iron core rotor, and permanent magnet rotor. The fixed coil of the generator motor is a fixed coil of a four-pole generator motor and a six-pole generator motor other than the two-pole generator motor. The odd number is the input line rotation excitation coil and the even number is the power generation coil, or the odd number is the input line rotation excitation coil and the even number is As the location number coil, the fixed coil of the 2-pole generator motor is arranged in the outer slot of the serial number that is clockwise when viewed from the direction of the rotation axis. The coil to be installed is a power generation coil, the coil disposed in the inner slot is a rotation excitation coil, the number of coil turns of the same location number coil as the power generation coil, and the outer coil and the inner coil of the same location number coil are wired in parallel. The number of coil turns is the same as the number of turns of the input line rotation excitation coil, or a slightly smaller number of turns, or as half the number of turns of the coil, the series wiring output line coil and the power generation coil By reducing the number of turns, the coil is arranged so that the excitation of the output coil when output from each coil is weakened so that it does not become a load on the rotation of the rotor. The method of output from the terminal block to which the coil is connected is applied to all the described generator motors, and each UVW three-phase generator coil arranged in the generator motor uses the left and right copper wires of the generator coil as left output lines. Set the right output line to single-phase power generation for all coils and single-phase output at each output terminal block by number, or bundle the same-direction output lines of three-phase UVW power generation coils into three bundles at each terminal block by number Neutral point, output wires in opposite directions are set to three-phase star connection output at each terminal block, or output terminal blocks that are star-connected to each terminal block are gathered at one place to be a combined terminal block star connection output Alternatively, the neutral point of star connection in the collective terminal block may be removed, and the delta connection in the collective terminal block may be used for delta output. Also, a three-phase series of generator motors with built-in iron core rotor and cage iron core rotor A little if a three-phase capacitor is attached to the wiring output line Storage batteries that convert the alternating current with the electromotive force output from the output terminal block a little higher than the storage battery voltage to direct current through a rectifier and connect the direct current to the storage battery and the conversion device with an electric wire as the power consumption is reduced , Lead storage battery, lithium ion storage battery, electric double layer capacitor, storage battery that mixes quick charging and normal charging, and direct current output through inverter or DC converter while keeping the storage battery charged because the DC voltage is high, DC-DC or DC-AC as DC-DC or AC converted to 100V, 200V, 300V, 400V, converted into direct current or alternating current, applied to the inverter driving the generator motor, and one or two generator motors An AC that has been rotated in conjunction with the electromotive force output from the output terminal block to a voltage slightly higher than the battery voltage is returned to the rectifier. (B) The front and rear of the generator motor and the coil direction applied to all the generator motors described in (a) above are the front cover side of the rotating shaft power transmission shaft side of the generator motor. The stator yoke side to which the fixed coil lead copper wire is attached is the left-right direction as viewed from the direction of the rotation axis, and the slot number and coil number are the clockwise serial numbers. The description of the left and right direction, and the input line rotation excitation coil and the series wiring output line coil of each power generation motor are described as a left-handed coil, but the reverse direction of the coil winding direction described when current flows reversely from the neutral point The coil turns into an input line rotation excitation coil and a series wiring output line coil. The input and output lines of both coils are changed to the neutral point, and the neutral point that has been installed is changed to the input line rotation excitation coil. If it is changed to a column wiring output line coil, it becomes a right-handed coil, and a generator motor with a right-handed coil can also be made. The outer coil is a power generation coil, the inner coil is an input line rotation excitation coil, the three-phase UVW input line rotation excitation inner first coil is a left-handed coil, and the three-phase each UVW input line rotation excitation inner second coil is a right-handed coil. The three-phase UVW input line rotational excitation No. 1 coil winding copper wire is used as the (1, 2, 3) input wire, and the three-phase input line rotational excitation No. 2 coil winding copper wire is (1, 2). 3) The input wire, the copper wire at the end of each coil is the neutral point (4, 5, 6), and the left and right copper wires of each UVW power generation No. 1 coil and each UVW power generation No. 2 coil are left output lines. (7, 9, 11) and right The output wires (8, 10, 12) (c) The distributed winding coils of the two-pole generator motor are arranged in slots 1 to 36, the same location number coil, and the inner coil as the input line rotary excitation coil The outer coil is used as a power generation coil, the first coil winding of the three-phase UVW input line rotation excitation is started, the left-hand coil is arranged with the copper wire as the (1, 2, 3) input wire, and the three-phase UVW input line rotation excitation second coil winding. The first copper wire is used as a (1, 2, 3) input wire, a right-handed coil is installed, and the three-phase UVW input wire rotation excitation coil has a coil winding end copper wire as a neutral point (4, 5, 6). The coils are left and right copper wires (7, 9, 11) and right output wires (8, 10, 12) for the left and right copper wires of each UVW power generation No. 1 coil and each UVW power generation No. 2 coil. The distributed winding coil of the motor is used as the 1st to 24th slots. Arranged on the theta yoke, the odd number is the input line rotating excitation coil and the even number is the power generating coil. The first winding of the U-line input line rotating excitation coil starts and the left-hand coil is disposed with the copper wire as the input line (1). The winding end copper wire is the left coil in the third coil, the winding end copper wire is the U neutral point (4), and the U generator coil is the left and right copper wires of the second and fourth coils. (7) and right output line (8), V-line input line rotational excitation No. 1 coil winding start copper wire is input line (2), left-handed coil is arranged, winding end copper wire is arranged in No. 3 coil and left-handed coil arrangement The copper wire at the end of winding is V neutral point (5), and the left and right copper wires of the 2nd and 4th coils are the left output line (9) and right output line (10) for the V power generation coil. Rotation excitation No. 1 coil winding start copper wire as input line (3) The left-handed coil is disposed on the third coil and the winding-finished copper wire is the W neutral point (6), and the W power generation coil is the left and right copper wires of the second and fourth coils as the left output line (11). A single-phase power generation coil with the right output line (12) (e) A distributed winding coil having a 1-phase and a 3-phase same winding coil and a 2-phase reverse winding coil of a 4-pole power generation motor Arranged on the stator yoke of the slot, the odd number coil is the input line rotary excitation coil and the even number is the same place number coil, the outer coil is the generator coil, the inner coil is the serial wiring output line coil, and the input line rotary excitation coil is in series Arrangement of the wiring output line coil with the 1-phase and 3-phase left-handed coils and the 2-phase right-handed coil is the left-handed coil arrangement with the copper wire in the 1st slot as the input line starting from the 1st coil of the U-line input line rotational excitation. Set coil end 11 No. 3 slot copper wire is left coiled on No. 3 coil, coil winding end No. 35 slot copper wire is U neutral point, U series wiring output line No. 2 coil winding start No. 14 slot copper wire is output The left winding coil is arranged as a wire, the coil winding end copper wire is arranged at the 4th coil, the left winding coil is arranged at the 4th coil, and the copper wire of the 47th slot at the coil winding end is set as the neutral point in the U location. As the left and right copper wires of the No. coil, the No. 13 and No. 37 slot copper wires are used as the left output wires, and the No. 24 and No. 48 slot copper wires are used as the right output wires. Copper wire as the input wire, right-handed coil arrangement, slot-finished 6th slot copper wire, 3rd coil with right-handed coil arrangement, winding-end 30th slot copper wire as V neutral point, V series Wiring output line 2 The winding of the 27th slot is used as the output wire and the right-handed coil is placed at the end of the coil winding, and the right-handed coil is placed as the 4th coil. The V generator coil is the left and right copper wires of the 2nd coil and the 4th coil, the 17th and 41st slot copper wires are the left output wires, and the 28th and 4th slot copper wires are the right output wires. Line input line rotational excitation First coil winding No. 9 slot copper wire is used as an input line, left-handed coil arrangement, coil winding end No. 19 slot copper wire is No. 3 coil, left-handed coil arrangement, coil winding end No. 43 The slot copper wire is W neutral point, W series wiring output wire No. 2 coil winding start No. 22 slot copper wire is output left winding coil arrangement and coil winding end copper wire is No. 4 coil left winding coil The coil winding end No. 7 slot copper wire is the neutral point at the same location, and the W generator coil is the left and right copper wires of the No. 2 coil and No. 4 coil, and the No. 21 and 45 slot copper wires are the left output wires. No. 32 and No. 8 slot copper wires were used as the right output line. (F) Distributed winding coils of 4-pole motors were arranged in the stator yoke as No. 1 to No. 48 slots, and odd-numbered coils were used for input line rotation excitation. The arrangement in which the even number coil is the same location number coil, the outer coil is the power generation coil, the inner coil is the serial wiring output line coil, and the input line rotation excitation coil and the serial wiring output line coil are the left-handed coils. Input wire rotation excitation The first coil winding copper wire is the input wire (1) and the left-handed coil is arranged. The coil winding end copper wire is the third-winding coil and the left-winding coil is arranged. Point (4), U series wiring output line No. 2 coil winding start copper wire is output line (14), left winding coil is arranged and coil winding end copper wire is No. 4 coil left winding coil is arranged and coil winding end The copper wire is the U-position neutral point (17) and the left and right copper wires of the 2nd and 4th coils are the left output line (7) and the right output line (8), and the U generator coil rotates the V-line input line. Excitation No. 1 coil winding start copper wire is input wire (2), left-handed coil is arranged and coil winding end copper wire is No. 3 coil left-handed coil is arranged, and coil winding end copper wire is V neutral point (5) , V series wiring output line No. 2 coil winding start copper wire is the output line (15) left winding coil arrangement, coil winding end copper wire is No. 4 coil left winding coil arrangement, coil winding end copper wire V Place neutral point (18), V generator coil No. 2 The left and right copper wires of the coil and No. 4 coil are the left output line (9) and the right output line (10), the W wire input line rotational excitation No. 1 coil winding start copper wire is the input line (3), and left-handed coil arrangement The coil winding end copper wire is arranged as a left-handed coil on the third coil, the coil winding end copper wire is set to the W neutral point (6), and the W series wiring output line No. 2 coil winding start copper wire is set to the output line (16). The left-handed coil is installed and the copper wire at the end of the coil is placed in the left-handed coil at the No. 4 coil. The copper wire at the end of the coil is the W neutral point (19). The copper wire is the left output line (11) and the right output line (12). (G) The distributed winding coil of the 6-pole generator motor is placed in the stator yoke with slots 1 to 36, and odd numbers are input lines. A rotating excitation coil with an even number as a generator coil The arrangement in which the input rotation excitation coil is a left-handed coil is that the U-wire input line rotation excitation first coil winding start copper wire is the input wire (1), the left-hand winding coil is disposed, and the coil winding end copper wire is the third coil. A left-handed coil is disposed and a coiled end copper wire is disposed on the fifth coil. A left-handed coil is disposed on the fifth coil and the coiled end copper wire is defined as a U neutral point (4). The left and right copper wires of the No. 6 coil are the left output line (7) and the right output line (8), the V-line input line rotational excitation No. 1 coil winding starts the copper wire as the input line (2), and the left-handed coil is arranged and coiled The winding end copper wire is arranged in the left coil in the third coil, the coil winding end copper wire is arranged in the left winding coil in the fifth coil, and the coil winding end copper wire is set to the V neutral point (5). Left and right copper wires of 2nd coil, 4th coil and 6th coil Output wire (9) and right output wire (10), W wire input line rotational excitation No. 1 coil winding start copper wire is input wire (3), left winding coil is arranged and coil winding end copper wire is No. 3 coil A left-handed coil is disposed on the left winding coil, a left-handed coil is disposed on the fifth coil, and the winding-finished copper wire is defined as a W neutral point (6). The left and right copper wires of the number coil are the left output line (11) and the right output line (12). (G) The distributed winding coil of the 6-pole power generation motor has slots 1 to 72 and is arranged on the stator yoke. The number is an input line rotation excitation coil, the even number is the same location number coil, the outer coil is a power generation coil, the inner coil is a series wiring output line coil, and the input line rotation excitation coil and the series wiring output line coil are left-handed coils. The setting is U line input line rotation excitation 1 The coil winding start copper wire is the input wire (1) and the left winding coil is arranged. The coil winding end copper wire is arranged in the third coil and the left winding coil is arranged. The coil winding end copper wire is arranged in the fifth coil and the left winding coil is arranged. The winding end copper wire is the U neutral point (4), the U series wiring output line No. 2 coil winding start copper wire is the output line (14), the left winding coil is arranged, and the coil winding end copper wire is left-handed around the No. 4 coil The coil is arranged and the coil winding end copper wire is arranged on the 6th coil and the left winding coil is arranged on the 6th coil, and the winding end copper wire is set as the neutral point (17) at the U location, and the U power generating coil is the 2nd coil, 4th coil and 6th coil. The left and right copper wires of the coil are the left output line (7) and the right output line (8), the V-line input line rotation excitation No. 1 coil winding start copper wire is the input line (2), the left-handed coil is arranged, and the coil winding end copper Place the left-handed coil on the No. 3 coil and coil The copper wire at the end of the winding is arranged in a left-handed coil in the No. 5 coil, the copper wire at the end of coiling is set to the V neutral point (5), and the winding of the V series wiring output line No. 2 coil is started as the output wire (15). Coil arrangement, coil winding end copper wire, left winding coil arrangement in No. 4 coil, coil winding end copper wire arrangement, No. 6 coil left winding coil arrangement, coil winding end copper wire in V same location neutral point (18) The left and right copper wires of the 2nd coil, 4th coil, and 6th coil are the left output line (9) and the right output line (10), and the V power generation coil is the W line input line rotational excitation first coil winding start copper wire To the input wire (3), the left-handed coil is arranged, the coiled end copper wire is arranged in the third coil, the left-handed coil is arranged, the coiled-end copper wire is arranged in the fifth coil, and the coiled-end copper wire is arranged. W neutral point (6), W series wiring output line No. 2 The coil winding start copper wire is the output wire (16) and the coil winding end copper wire is arranged in the left coil in the No. 4 coil, the coil winding end copper wire is arranged in the No. 6 coil, and the coil winding end copper wire is arranged in the left coil. The neutral point (19) at the same location as W, and the left and right copper wires of the second coil, the fourth coil and the sixth coil as the left power line (11) and the right output line (12) for the W power generation coil Stator yoke with 6-pole generator motor distributed winding coil No. 1 to 72 slot, 1 phase and 3 phase same winding coil and 2 phase reverse winding coil, odd number is input line rotation exciting coil The even number coil is the same place number coil, the outer coil is the power generation coil, the inner coil is the series wiring output line coil, the 1-phase and 3-phase are the left-handed coils, and the 2-phase is the right-handed coil. Input line rotation excitation No. 1 carp The left winding coil is arranged with the copper wire of the first slot at the beginning of winding as the input wire, the coil winding end copper wire is arranged in the left winding coil in the third coil, and the coil winding end copper wire is arranged in the left winding coil in the fifth coil. The copper wire of the 59th slot at the end of winding is the U neutral point, the winding of the 2nd coil of the U series wiring output wire is the output wire of the 14th slot, and the left winding coil is arranged. The left-handed coil is disposed on the left end of the coil and the copper wire at the end of the coil is disposed on the sixth coil. The left-handed coil is disposed on the sixth coil. The left and right copper wires of the coil and No. 6 coil, the copper wire of the No. 13, 37 and 61 slots as the left output line, the copper wire of the No. 24, No. 48 and No. 72 slots as the right output line and the V input line Rotation excitation No. 1 coil winding Beginning with a 16th slot copper wire as an input wire, a right-handed coil is placed, a coiled end copper wire is placed in a 5th coil, a right-handed coil is placed, and a coiled-end copper wire is placed in a 3rd coil Coil winding end 30th slot copper wire is V neutral point, V series wiring output line No. 2 coil winding start 27th slot copper wire is output line, right winding coil is arranged, coil winding end copper wire is 6 The right-handed coil is placed in the No. coil and the copper wire at the end of the coil is placed. The right-handed coil is placed in the No. 4 coil, and the copper wire at the end of the coil winding in the slot No. 42 is the neutral point of the V. The left and right copper wires of coils No. 4 and No. 6 are used as the left output wires, and the copper wires of No. 28, No. 52 and No. 4 slots are used as the right output wires. W line input line rotation excitation No. 1 coil winding start The 9th slot copper wire is used as the input wire, the left-handed coil is arranged, the coiling end copper wire is arranged in the 3rd coil, the left-handed coil is arranged, and the coiling end copper wire is arranged in the 5th coil and the left-handed coil is arranged. The 67th slot copper wire is the W neutral point, the W series wiring output line is the 2nd coil winding start, the 22nd slot copper wire is the output line, the left-handed coil is arranged, and the coil winding end copper wire is the left-handed winding on the 4th coil Coil arrangement and coil winding end copper wire, coil No. 6 left winding coil arrangement and coil winding end No. 7 slot copper wire as neutral point W, W power generation coil is No. 2 coil and No. 4 coil The left and right copper wires of the 6th coil, the copper wires of the 21st, 45th, and 69th slots are the left output wire, and the copper wires of the 32nd, 56th, and 8th slots are the right output wires. (C) The extension using the generator motor described in claim 1 is an odd-numbered input line rotational excitation coil and an even-numbered power generation coil, or an odd-numbered input line rotational excitation coil and an even-numbered same-position number coil. Or increase the number of generator motors to be increased by the same number of poles and the same coil winding direction, and arrange the power transmission rotary shaft side in the same direction and arrange them side by side. The rotating shafts are combined with flanges facing each other, or three units are arranged in a triangle, and the power transmission rotating shaft side is directed in the same direction to concentrate the rotational force on the center of the triangle and use it as a surplus power As an additional number of generator motors, the odd number of the generator motor is an input line rotation excitation left-handed coil, the even number is the same place number coil, the outer coil is a generator coil, and the inner coil is a series wiring output line left-handed coil. The inverter three-phase output line is connected to the No. 1 generator motor input line rotation excitation coil with a star or delta connection, and the three-phase electric wire attached to the No. 1 generator motor series wiring output line is rotated on the No. 2 generator motor input line. A timing belt, pulley, and V-belt are connected to the rotating shaft of the generator motor, which is connected to the exciting coil and connected to the No. 3 generator motor input line rotation exciting coil by connecting the three-phase electric wire connected to the series wiring output line of the No. 2 generator motor. In order to prevent the rotation position timing from deviating by interlocking with the additional generator motor, each generator coil is connected in star connection or delta connection, and a low voltage electromotive force is generated from the collective terminal block. Is the output of the No. 2 generator motor and the No. 3 generator motor input line rotational excitation coil star or delta, and the high voltage electromotive force is the output, or the No. 1 generator motor Remove the inverter output line attached to the input line, leave the wire wiring between the extension and the generator motor as it is, and rotate the rotary shaft of the No. 3 generator motor with the power motor, generator motor, gasoline or light oil engine power rotary shaft with pulley and V belt When the rotation shaft of the No. 3 generator motor is rotated, the rotation of the No. 2 motor and the No. 1 motor is not necessary to synchronize, and the generator motor having a smaller number of coil turns is changed from the generator motor having a larger number of coil turns of the fixed coil. When an electromotive force is applied to the motor, the rotation is followed by the generator motor with a large number of coil turns and the generator motor with a small number of coil turns, and the timing belt is not required. A timing belt is not required even when the magnet rotor and iron core rotor of the generator motor are combined. The number of generator motors that are rotating and the generator motor fixed coil is an input line rotation excitation coil and generator coil is increased by multiple. The rotating motor is installed on the rotating shaft to match the timing, connecting the generator motors in order from the input line rotational excitation to the input line rotational excitation in the order of star or delta connection with a three-phase wire, Assuming that increased power generation can be achieved by rotating the rotating shaft of any number of generator motors with power, the output from the connection part of the input line rotation excitation coil is a high voltage electromotive force, and the output of each power generation coil is a low voltage electromotive force. The output line is an aggregate terminal block output with a star connection or a delta connection, and the rotors of all installed power generation motors are made to have a strong magnetic force, or power generation that gradually weakens the rotor's magnetic force from the first power generation motor. The motor is installed, the input line rotation excitation coil and the series wiring output line of the strong magnetic rotor are delta connection, and the input line rotation excitation coil and the series wiring output line of the weak magnetic rotor are star connection. To move the rotor in parallel from the theta yoke, it is assumed that the rotor is pushed out or the rotor is pulled out, and the rotor shaft of the generator motor is stored in the stator yoke at a fixed position, or the rotation speed The stator yoke is moved in parallel and fixed in a place that matches the application of the generator motor, or the rotor is put out, or the outside of both bearings that fix the entire rotating shaft rotor with the stator yoke in place is inside the bearing case In order to move the rotor of the rotating shaft in parallel, or to move the rotor of the rotating shaft in parallel, a polygon with a parallel moving length to the rotating shaft is processed directly into the rotating shaft to form a power transmission polygon. The rotor that has been processed into a polygonal cylinder at the center can also be moved in parallel by sliding on the polygonal surface, or the workpiece can be placed on the rotating shaft without being processed directly on the rotating shaft. A hole is made in the center processed into a polygonal column with the moving length, and a rotary shaft is press-fitted into a power transmission polygonal column. A polygonal column hole is machined in the center of the rotor and the rotary shaft polygonal column (52) enters and slides on the polygonal column surface. The rotor is moved in parallel, and the power transmission polygonal column on the rear lid side is projected 10 mm from the rotor. The extracted polygonal column is a part that enters the push pipe (55), and the electromagnet is processed from the stator yoke into a polygonal column. The rotor and the magnet insertion iron core rotor were pushed by the push pipe (55) to move the rotor in parallel. (I) The rotor fixing bracket with the neodymium magnet provided in the center holed fan-shaped magnet rotor and the processing on the rotor The groove (39) in which the power transmission of the length of the parallel movement distance enters the place divided into the number of poles from the fixed position is processed into a power transmission plate groove (39) by machining the groove parallel to the perpendicular to the center of the rotating shaft. , Magnet presser prevention material And the power transmission plate are combined into a T shape, and the rotating shaft side of the T-type power transmission plate turning prevention material is inserted into the power transmission groove (41), and a divided pipe (33) is disposed between the grooves. The disc with the disc arranged so as to hold down is a welded fixed disc (38) with a through-bolt hole for fixing the air-cooled fan and the central perforated fan-shaped magnet on the front lid side. Type power transmission plate turning-up prevention material is welded and fixed (42), and it is confirmed that it slides on the rotating shaft in parallel. The rotor fixing disk (34) is arranged so as to hold the part where the split pipe is brought out to the lid side after 10mm by the fixed disk (34). The rotor fixing disk has a through bolt hole and a T-type power transmission plate turn-up prevention material. A lower stage is provided on the outer peripheral side, and the through bolt (32) is fixed by welding. Bolts are inserted from the front lid side of the board, passed through the rotor fixing disk bolt holes, and tightened with nuts to make the rotor fixing bolts and the nuts to prevent rotation. T-type power transmission arranged on the outer peripheral lower side of the rotor fixing disk (34) The tip of the plate curl prevention material (35) is machined into a V-shape, and the V-shaped curl prevention material is bent 90 degrees from the lower outer side of the rotor fixing disk toward the rotation axis, and a hole is made in the rotor fixing disk and the V-shaped curling prevention material. An internal air cooling fan (53) of the generator motor is disposed on the front lid side of the rotary shaft rotor which is fixed by the nut and is prevented from rotating around the nut side, and the fan is disposed on the rotary shafts of all the generator motors. May be made of stainless steel or stainless steel material that reacts slightly to the magnet's attractive force. The length of the magnet is 37 mm, the thickness of the central perforated fan-shaped magnet (37) disposed on the rotor is 10 mm, and the number of magnet poles arranged is 11:15:11. The ratio between the holed fan magnet and the 200V input line rotary excitation coil is the best ratio, and the number of centered holed magnets required for rotor production can be predicted. The height of the perforated fan-shaped magnet (40) is 35 mm, the space to the center is 40 mm, and the ratio of the height of the magnet to the distance from the rotating shaft side of the magnet bottom to the center of the stator yoke is 7 pairs. The generator motor with the arrangement of 8 is the most compatible ratio and the diameter of the rotating shaft can be predicted. (C) The generator motor case in which the parts and the workpieces of claims 1 and 2 are arranged inside and outside has a cylindrical appearance, and the fixed bases arranged on both front and rear sides of the generator motor case are motors. A power generation motor case with a flat bar rib that is reinforced inward on an angle leg with the angle parallel to the case, horizontal and outward, and the part that contacts the motor case is welded. Bolt hole squares to be arranged are evenly arranged on the outer circumference of the front and rear of the motor case, and a low-cooled air-cooled air jump ring (63) is welded to the inner side of the rear cover side motor case. One or two holes for the input and output lines are drilled, and the hole where the input terminal block and output terminal block are placed above the drilled hole is provided with a rubber edge to prevent dust entry or leakage. And on the rear cover of the generator motor There are different types of lids, and the lid with the same type of front lid and rear lid, and the rear lid different from the front lid are different in the arrangement of the bearing case, and the front and rear lids have a larger outer diameter by about 3 mm than the outer diameter of the motor case cylinder. The outer edge of the motor case cylinder is the edge where the outer periphery of the motor case cylinder enters, and the outer periphery of the inner side of the cover and the lid side of the edge are welded and fixed so that the center of the rotating shaft does not shift. At the edge of the lid used as the lid of the generator motor, bolt holed square material is welded to the edge of the bolt hole square material attached to the motor case. The inner periphery of the rim and the outer periphery where the motor case enters are lathe processed, or the width of the rim from the inner side of the lid, which is not to be turned, is 10 mm to 50 mm, and the rim width is determined by the motor case diameter. bearing A filter is attached to the air suction port (45) of the front lid, which is a front lid in which an air suction port is opened between the reinforcing plate and the reinforcing plate. Attach the pipe to a place where there is no air debris, attach a shock absorber to the extended pipe, place a magnet inside it, and adsorb iron powder etc., and open the back cover as the same cover as the front cover The bearing case of the rear lid is assumed to be used as an air discharge port (50) or as an air discharge forced electric fan port (50). The length of) is the lathe machining on the inside of the bearing case, which is the sum of the rotor translational distance and the thickness of one or two push bearings. The push bearing (30) is the inside of the bearing case and the rotation axis of the push bearing. And slip A rotor push pipe whose rotor is moved in parallel by a rotor push pipe (31) after the push bearing has moved is a fan-type magnet with a central hole that can be manually inserted into the rotary shaft and there is no gap in the rotary shaft. As a push pipe for the rotor, the length of the push pipe (55) of the polygonal column rotor is such that the position where the polygonal column is projected 10 mm from the rotor to the rear lid side is the rotor fixed position, and the outside where the polygonal column is projected 10 mm is placed in the pipe The inner diameter of the pipe with no gap in the polygonal cylinder and the length to the push bearing is the length of the rotor push pipe, and the lid attached to the rotor push pipe on the bearing side is a plain washer with a hole in the diameter of the rotating shaft, Alternatively, the ring is used as a lid, and a projection (56) is formed on the entire circumference of the lid where it hits the lid and the bearing rotating part on the rotating shaft side, and the lid protruding part is pushed and pushed by the rotating part on the bearing (30) rotating shaft side. Is (1) The bearing push pipe (23) that translates the push bearing on the rear lid side is a bearing push pipe that is inserted into the inner diameter of the bearing case that penetrates to the outside of the rear lid. The bearing push pipe with the length of the parallel movement distance covered, the bearing push pipe cover (23) with a nut or screw at the center, and a bearing with a non-rotating cut on the outer periphery of the cover Cover the outside of the push pipe lid with a large push bolt pedestal pipe, attach the lid to the covered pipe, and make a bolt pedestal pipe lid (24) with a push bolt hole in the center of the lid. Pass the push bolt through the nut of the bearing push pipe lid (23) through the push bolt, and release the push bolt rotational force to the inside of the bolt cradle pipe lid lid. The prevention plate (21) is fixed to the push bolt, the bearing push pipe and the rotor are moved in parallel by tightening or loosening the push bolt, and the bolt cradle pipe lid is fixed to the outer side of the rear lid. A straight gear (26) is arranged on the side of the cradle pipe cover, the pipe on the top of the gear is cut into a long and narrow shape, a moving measurement gear (27) attached to the bearing push pipe cover (23) is taken out, and the teeth are combined with the linear gear. The spring interlocking material (28) attached to the moving measurement gear is connected to the inverter volume dial, and when the bearing push pipe moves in parallel, the dial rotates and the inverter frequency is changed. The hydraulic cylinder (49) is arranged in the middle of the bolt cradle pipe lid, and the hydraulic pump rotates the hydraulic pump by the rotation of the rotating shaft, Or, the electric hydraulic pump is rotated by the generated electricity, and an operation lever is attached to the hydraulic pump that pushes the push bearing with the hydraulic cylinder, and the rotor is made parallel with the hydraulic cylinder as the lever position that is the push side, neutral, and return side. (Ii) The manufacture and fixing of the stator yoke thin plate laminated material arranged in the generator motor case is the same as the slot of the input line rotation exciting coil and the slot of the generator coil when manufacturing the thin plate, or a slightly smaller slot Alternatively, a gap member (57) in which a stator yoke manufactured as a half-sized slot is fixed by sandwiching the stator yoke in the stacking direction with protrusions provided at both ends of the gap member, The stator yoke is welded to the gap material that is evenly arranged on the outer peripheral side and has the length of the stator yoke, and the stator yoke is welded from the gap material holes that have several holes. The yoke and the gap material are fixed by welding, the stator yoke fixed by the gap material is disposed in the motor case, and the space between the gap material and the gap material between the motor case and the stator yoke is defined as an air passage (51). An internal air-cooling fan that is formed on a rotating cone inside the motor case by processing a wide thin plate inside the motor case from the outside of the front lid edge to the inside of the motor case so as to wrap the entire air suction port from the outside with a truncated cone from the inside of the front lid The air-inducing air direction indicator plate (54) fixed to the bottom and the flow of flowing the air from the internal air-cooling fan (53) attached to the front lid-side rotating shaft to the rear lid side is sent by the air guide (61). The air guide material that is to be guided to the gap material air passage (51) is also a truncated cone, and is a half cone height of the copper wire coming out of the slot, or a wide truncated cone on the gap material side from above the copper wire. Fixed circle Generator motor base is of a material that is a thin insulator