JP6083847B1 - A generator in which a non-adsorption slot power generation coil and a separation coil are arranged in parallel or obliquely. - Google Patents

Abstract

An output excitation in a coil is weakened to generate low speed rotation with low torque power and a generator to generate high speed rotation with a transmission to reduce the fuel cost and power consumption of the engine or motor by half. Power generation in which non-adsorptive slot power generation coils are arranged in parallel or obliquely to weaken the output excitation and power generation in which the coils are separated into an outer coil and an inner coil and the output excitation is extinguished from the inner surface of the coil. [Selection] Figure 4

Description

  The present invention relates to a generator.

  A generator in which a stator yoke slot is provided with a multi-winding power generation coil having the same number of rotor poles or a three-phase distributed winding power coil with the number of rotor poles.

Japanese Patent No. 4951099

  The problem to be solved is that when the electromotive force is output from the generator coil to the load side, the output excitation generated in the coil is weakly magnetized, or the output excitation is extinguished, and the generator side is rotated at low speed with low torque power. Is it possible to halve the fuel or power consumption on the power side using a rotating transmission?

  The present invention provides a stator yoke in which a stator yoke has a cylindrical shape, an inner circumference into which a rotor is inserted is also circular, and is laminated with a thin electromagnetic steel sheet cut into a donut shape without a slot, and a stator yoke inner circumference having no iron slot The non-adsorptive slot instead of the iron slot is used as a stator yoke, and the non-adsorptive slot does not adsorb stainless steel, aluminum, acrylic plate, polyvinyl chloride resin, glass fiber, rubber, vinyl hose, slot sheet, etc. Non-adsorptive processed into U-shape, U-shape, round pipe shape, and oval shape as a non-adsorption slot cut with a dimension slightly longer than the stator yoke length. A slot sheet is provided for the energized member of the slot, and no slot sheet is provided for the non-energized member. A power generation coil is inserted into a non-adsorptive slot that is fixed to the circumference of the stator yoke with the opening facing the rotor, and the non-adsorptive slot is fixed by welding, screwing, or resin rubber glue. In addition, the non-adsorptive slot power generation coil fixed by a thread, a binding band, and a fusion tape is used as a non-adsorptive slot power generation coil that is fixed by a thread, a binding band, and a fusion tape. In order to prevent the copper wire from popping out of the opening, the slot sheet and non-adsorptive slot covered by the opening are made non-adsorptive slots bonded with resin rubber glue and vinyl resin of hot melt adhesive, and the stator yoke arrangement of the non-adsorptive slot generator coil The number of rotor poles is the same as the number of rotor poles in the generator coil, 2-pole rotor, 4-pole rotor, 6-pole rotor, and 6-pole rotor type 3-pole rotor. A multi-winding power generation coil, a three-phase power generation coil with the number of rotor poles, a two-phase power generation coil, a one-phase power generation coil, or a non-rotated coil disposed on the stator yoke The suction slot power generation coil is a non-suction slot power generation coil arranged parallel to the rotation direction of the rotary shaft rotor with respect to the rotary shaft rotor installed horizontally, or slanted with respect to the rotary shaft rotor. Non-adsorptive slot power generation coils arranged diagonally parallel to the rotation direction, or an arrangement angle of 10 to 45 degrees or non-adsorptive slot power generation coils disposed at an oblique angle as much as possible The separated non-adsorptive slot power generation coil is used as the separation coil, and the non-adsorptive slot power generation coil or separation coil is rotated while the rotor magnetic flux rotates while attracting the circumference inside the stator yoke. The advantage of the non-adsorptive slot power generation coil arranged in parallel is that it is easy to manufacture and the rotor is separated from the position where output excitation occurs. The advantage of the non-adsorptive slot power generation coil arranged diagonally in parallel is that the magnetism attracting the output excitation and the rotor magnetic flux is weakened as a position, and the advantages of the non-adsorptive slot power generation coil arranged diagonally in parallel appear As the magnetic flux between the rotor output parallel to the oblique output excitation rotates and the magnetic flux attracts in a small range where the oblique and parallel cross, the output excitation and the rotor magnetic flux can be separated by low speed rotation. When a force of 10 is required to separate the permanent magnet in a state where the permanent magnet is attracted in parallel with a gap, one of the two elongated magnets is moved from 45 degrees to 5 degrees. It is possible to dispose with an oblique power generation coil utilizing the fact that it can be separated by a force of 5 when tilted at a degree, and the output wiring of the non-sucking slot power generation coil can be a single-phase output for each power generation coil, or a rotor The generator coils that pass through the same poles of the coil at the same time are connected in series, and the coil winding starts with the copper wire as the output wire, and the coil winding ends with the copper wire as the neutral point. The winding end of the non-adsorptive slot generator coil is the neutral point, the three wires are star-connected or delta-connected, and the wiring starts from the output line to the three-phase output. The advantage of the separation coil that separates the coil into the inner coil and the two generation coils is that the AC coil is output in the same direction to the coil separated into the outer coil and the inner coil. A separate coil that utilizes the fact that output excitation disappears only when there is no neutral point of single-phase output from the rotor side surface in the power generation coil. The extinguished output excitation is the magnetic field lines of the outer and inner coils inside the stator yoke. However, the rotor's repulsive magnetic flux reaches the output excitation embedded in the stator yoke, and the rotor rotation slightly increases during output of the electromotive force. As for the generator coil and the rotor that are arranged or constructed as follows, the width of the stator yoke is set to a width of the stator yoke that is 1.5 to 2 times larger than the length of the non-sucking slot, or non-sucking To increase the number of coil turns and reduce the rotor diameter by increasing the length of the slot on the rotor side, the height of the fan-shaped magnet is shortened, and the shape of the rotor fan-shaped magnet on the coil side The rotor was used as a rotor with a gap adjusted so that the outside of the rotor was positioned in the range where the output excitation of the stator yoke was weakly magnetized. A rotor using a neodymium magnet as a fan-shaped magnet rotor, connecting the non-adsorptive slot power generation coil installed in the stator yoke between the coils, or other The coil is connected to the end of the coil winding, and the lead-out copper wire that leads the copper wire out of the stator yoke is prevented from leaking a little thicker than the coil copper wire at the position slightly out of the generator coil. Connect the lead-out copper wire to the generator, and connect the lead-out copper wire, which has been connected to the generator, with shrink tube, vinyl tape, fusion tape, and glass fiber to prevent leakage. It is assumed that the single-phase or three-phase leakage preventer input terminal of the operation panel arranged on the rear cover is wired, rectified from the output terminal, and wired as DC and AC from the voltmeter to each output terminal or plug. The generator should be a non-adsorptive slot generator coil generator with or without a generator case.

Reading the specification, the power transmission side of the rotating shaft is the front side of the generator, the stator yoke, and the rotor, the opposite direction is the rear side, the rotor side of the stator yoke is the inside, the case side is the outside, and the inside and outside lengths are The width, the stacking direction of the stator yoke is the stacking length, and the number 1 of the non-sucking slot disposed inside the stator yoke is the right-handed serial number from the 1st slot where the position can be set to 1 The left and right sides of the suction slot power generation coil are the left coil copper wire and the right coil copper wire of the coil when viewed from the direction of the rotation axis, the multi-winding non-adsorption slot power generation coil or the outer coil and the inner coil, and the height of the non-adsorption slot is the stator yoke The range that does not contact the rotor from the inside is the height, and the multi-winding power generation coil is a coil with a width that is wide from the center position to the left and right from the center position indicated by the angle, The position of the non-adsorptive slot inside the stator yoke can be at any position. The non-adsorptive slot power generation coil is arranged in a diagonally parallel manner from the front side stator yoke to the rear side stator yoke, and is 10 with respect to the rotation axis. 45 degrees or 45 degrees from the angle, and as much as possible, the diagonal is more than 45 degrees, and the diagonal arrangement is diagonally up and down to the right from the front side of the stator yoke on the circumference of the stator yoke. The non-adsorptive slot power generation coils and the multi-winding power generation coils arranged diagonally and in parallel are the first, second, third, and sixth, seventh, and eighth slots. In the case of a triple winding power coil disposed in the No. 8 slot, the intermediate coil in the No. 2 and No. 7 slots, and the innermost coil in the No. 3 and No. 6 slots. Out of The wire is unified with the left copper wire and is easy to understand. However, when the wiring is reversed, the right coil copper wire is also used as the output wire, and the number of slots is increased to stabilize the rated output. The multi-winding generator coil has a constant output with a margin, the rotor poles are clockwise from the first pole to the sixth pole when viewed from the front of the generator, and the repulsive magnetic flux is the number of homopolar magnets in each rotor pole Dozens of sheets are arranged, and the repulsive homopolar magnets are tightened with bolts and nuts for close contact or fixed at a slight interval, and the magnetic flux raised on the coil side is fixed. The other side is on the top, and it is difficult to explain the generator, and the assembly method and work method are partly described.

The stator yoke is a stator yoke that uses a thin plate laminated material cut into a donut shape with a cylindrical outer diameter and a circular inner diameter as a magnetic yoke steel stator yoke, or a thin soft iron material, or an electromagnetic steel plate cut into a donut shape. A stator yoke in which one piece of soft iron is mixed and arranged with soft iron, and the length from the inner diameter to the stator yoke outer diameter to maintain the strength of the stator yoke is the height from the non-adsorptive slot toward the rotor side. The stator yoke width must be the same length or the stator yoke width longer than the non-sucking slot length so that the strength of the stator yoke does not become insufficient. The stator yoke is formed by stacking dozens of thin plates cut as the inner diameter of the stator yoke that has been cut into a circular shape with the length of the diameter. The stator yoke is fixed to a stator yoke that is fixed by one continuous welding at one place in the stacking direction at several locations on the outer periphery of the stator yoke and several circular portions inside the stator yoke. The laminated stator coil is longer in the copper wire and the electromotive force output to the load side is stabilized. The stator yoke is either a coated stator yoke or a stator yoke that has not been coated with varnish, and the height on the rotor side of the non-adsorptive slot power generation coil disposed on the inner diameter of the stator yoke is set so as not to contact the rotor. about

The non-adsorptive slot is a member that does not adsorb magnetic force, and is a slot that is arranged to place the coil copper wire in place in place of the iron slot, and the non-adsorptive slot is made of stainless steel, aluminum, PVC resin, glass fiber, acrylic A slot made of plate, vinyl, or plastic is processed into a U-shaped, round, U-shaped or elliptical shape, and a non-adsorptive slot fixed with the copper wire insertion port facing the rotor side. The non-sucking slot is bonded and fixed to the stator yoke inner diameter with resin rubber glue, or a round or square groove is processed on the stator yoke inner diameter, and the non-sucking slot also has a round or square projection on the stator yoke side. The non-adsorptive slot is fixed so that the protrusion of the non-adsorptive slot is inserted into a round or square groove on the stator yoke inner diameter so that it does not come out on the rotor side. The slot sheet is inserted into the non-adsorptive slot, but the slot sheet is not inserted into the non-adsorptive member, and the copper wire jumps out after the coil is installed in the non-adsorptive slot copper wire insertion slot. The prevention sheet is inserted into the non-adsorption slot, or the protrusion prevention sheet and the non-adsorption slot are bonded with resin-based rubber glue or vinyl resin of hot-melt adhesive after inserting the prevention sheet, round bar protrusion Has a small hole in the middle in the width direction of the stator yoke at the odd-numbered non-adsorption slot position, and a steel rod, aluminum rod, resin rod, wood rod, bamboo rod, and long bolt are inserted into the hole. A binding band that connects the non-adsorptive slot portion of the coil end protruding from the stator yoke of the non-adsorptive slot power generation coil disposed and the insertion rod of the protrusion, The fixing tape is used to fix both sides of the non-adsorptive slot generator coil from the front and rear sides of the stator yoke, and the intermediate part of the non-adsorptive slot is in contact with the stator yoke with resin rubber glue. The non-adsorptive slot was used, and the glass fiber was wound with the glass fiber after winding the copper tape around the left and right copper wire bundles within the stator yoke length range of the coil that had been wound with a certain number of turns. The non-adsorptive slot power generation coil is made by forming a wire bundle into an elliptical shape in the rotor direction and then mixing the polyester resin with a hardener and then solidifying the oval polyester resin. After the acrylic resin is poured into a mold with a height of 50 mm and cured, the slot is machined into the acrylic resin, or a non-suction slot The stator yoke of the non-adsorptive slot was processed with an opening on the rotor side after the acrylic resin was poured in and the non-adsorptive slot was fixed.

The position of the multi-winding non-adsorptive slot power generation coil may be any position on the inner diameter of the stator yoke at the zero degree position. 180 degree position, 2-pole rotor and multiple winding non-adsorptive slot generator coil arrangement at three positions, zero-degree position, 120-degree position, 240-degree position, 4-pole rotor and four winding positions, no multiple winding Arrangement of the suction slot power generation coil is a zero degree position, a 90 degree position, a 180 degree position, and a 270 degree position, and the arrangement of the 6-pole rotor and three multiple winding non-adsorption slot power generation coils is the zero degree position, A multi-winding non-adsorption slot power generation coil with width from side to side from the center position at 120 degrees and 240 degrees is arranged, and distributed winding non-absorption is applied to the 2-pole rotor, 4-pole rotor, 6-pole rotor and stator yoke. Slot power generation coil three-phase arrangement, the number of power generation coil copper wire arranged in the non-adsorption slot is one coil, two coils, three coils, four coils Coiled coils, non-adsorptive slot power generation coils wound in bundles are arranged parallel to or obliquely inside the stator yoke, and the parallel arrangement is parallel to the rotating shaft rotor installed horizontally. The non-adsorptive slot power generation coils are arranged in the rotational direction, and the oblique arrangement is 10 degrees to 45 degrees from the front stator yoke to the rear stator yoke with respect to the rotating shaft rotor installed horizontally or as oblique as possible. A multi-turn non-adsorptive slot power generation coil or a three-phase power generation coil of non-adsorptive slots arranged diagonally downward to the right angle or diagonally upward and arranged diagonally parallel to the rotor rotation direction, The serial wiring from the first power generation coil of the non-adsorptive slot installed to the other power generation coil is a serial wiring that connects the wiring from coil to coil or has no connection part from the coil winding start to the coil winding end. Coil crossover copper wire, coil output wire, and the coil side with the lead copper wire connected to the neutral point should be the stator yoke front side or the stator yoke rear side

The multi-winding power generation coil is described as an example in which a coil arrangement in which the coil width is kept constant and a coil arrangement in which the coil width is gradually widened are described. The multi-winding power generation coil arrangement in which the coil width is fixed to the non-adsorptive slot of the serial number is the first to seventh, second to eighth, third to ninth, fourth to tenth of the non-adsorptive slot The four-winding non-adsorptive slot power generation coil is disposed in a positional relationship, and the coil width is gradually increased so as to surround the inner coil with the outer coil of one multi-winding power generation coil. No.7, No.3 to No.8, No.2 to No.9, No.1 to No.10. Inner coil that is separated into two and extinguishes output excitation When using the outer coil, the 4th to 7th and 3rd to 8th coils are connected in series and wound in the same direction, and the 2nd to 9th and 1st to 10th coils are connected in series and wound in the same direction. Two series of double wound non-adsorptive slot power generation coils as outer coils and outer and inner coils in the same direction.

Stainless steel pipe, front disk, T-type power transmission plate, permanent magnet rotor fixed with through bolts and nuts, and a stainless steel pipe longer than the rotor length on the rotating shaft. The pipe is fixed to the front and rear of the pipe by spot welding, and the rotary shaft pipe is inserted into the hole made in the center of the front disk, and the front disk and the rotary shaft pipe are fixed by welding at the front disk position of the rotor. The fixed front disk is divided into the number of poles of the rotor, and T-type power transmission plates for the number of poles are arranged in the divided parts, and the part where the T-type power transmission plate, the rotary shaft pipe and the front disk are in contact is permanently welded. A magnet rotor fixing bracket, and a rotating shaft arranged in the order of a fan, a rotor and a rear bearing with an angle that changes depending on the rotation direction, which is sucked into and discharged from the rotating shaft, Use permanent magnets with strong magnetic force or neodymium permanent magnets as the permanent magnets arranged on each pole of the rotor. As a fan-shaped center hole fan-shaped magnet, an arc circle is formed on the coil side, and the rotating shaft side is also an arc circle. Or a straight fan-shaped magnet, or the central-perforated fan-shaped magnet with the coil side of the flat-shaped fan magnet with the coil side of the central-perforated fan-shaped magnet as the coil side and the magnetic axis The fan-shaped magnet with a central hole is arranged on the rotor, and the division range at one part of the front disk divided part divided into the number of rotor poles is the length in the rotation direction of the fan-shaped magnet. The thickness of the fan-shaped magnet is set in the length direction of the magnet, and the height of the magnet is set to the coil side from a position slightly spaced from the rotating shaft. The higher the height, the farther the magnetic force that pushes the repulsive magnetic flux to the coil side reaches. The height of the fan-shaped magnet was limited to be low in order to excite and attract the hidden output. In addition, the fan-shaped magnet with a hole in the center of the fan-shaped magnet has a central hole-shaped fan with a single hole with a central hole that has a lower step on the left and right ends of the coil side. The center hole of the mold magnet is a bolt through hole, the lower stage made to the left and right of the fan-shaped magnet is the lower stage where the T-type magnet holding parts of the left and right T-type power transmission plates arranged for the number of poles enter the front disk, and the front disk The first pole of the rotor is fixed at regular intervals with the same pole of the center holed fan-shaped magnet held on both sides by the T-type power transmission plate fixed at the position divided into the number of rotor poles toward the coil side A rotor with two pole rotors as N poles and S poles, N poles and N poles, S poles and S poles, a four pole rotor with rotors arranged alternately with N poles and S poles, and a six pole rotor with N poles A rotor with alternating and S poles and a 6 pole 3 pole rotor with either pole removed, and each rotor pole is a fan-shaped magnet Fan-shaped magnets are arranged between the T-type power transmission plate and the T-type power transmission plate of the front disk so that the stator yoke is attracted by the magnetic flux swelled to the coil side by the repulsive magnetic flux of the same polarity of The center hole fan-shaped magnet is fixed with a bolt that passes through the center hole of several center hole fan-shaped magnets from the outside of the front disk, or is tightened with a nut in a slightly spaced position and fixed. The T-type power plate magnet holding part at the same location as the nut fixing position is bent at 90 degrees on the rotating shaft side and inserted into the rotor magnet so that the fan-shaped magnet is fixed with the 90-degree bent part and the nut so that it does not pop out. The magnetic flux that repels both the pole and S pole, or the N pole and N pole, and the S pole and S pole rotor passes through the stator yoke and generates an eddy current in the case with a repulsive flux that reaches the generator case. Case as the case heats up The generator case with or without the case is made of aluminum or thick iron so that large eddy current does not occur in the case directly above the rotor. The outer side of the stator yoke was held down and fixed at several points, and the magnet used for the rotor pole was a neodymium magnet, but the permanent magnet was a fan with a central hole and the magnetic poles were magnetized on the rotating shaft side and coil side to repel. Any permanent magnet can be used as a rotor as long as it is a magnetic flux rotor, and when the electromotive force of a rotor in which the rotor is an N-pole rotor and an S-pole rotor is rectified, the rotor is rectified to plus and minus, and The rotor and the electromotive force do not change, and the only way to increase the voltage is that the rotor in which the N pole and the S pole are alternately arranged can increase the voltage at a low speed except for the 2-pole rotor, Axis of rotation The rotor is made of N pole and N pole, S pole and S pole, and the rotor shaft is made of stainless steel or weakly attracted to the magnet, and the bearing used is made of stainless steel and the shaft is magnetized by magnetic flux. It was decided to prevent the bearing from adsorbing and generating heat due to friction.

The generator without a case uses a stator yoke with a stator yoke fixed by welding, and a bearing case is attached to the center of the lid of the front and rear lids. The edge that protects the coil ends inside the front and rear lids. There are several holes on the front and rear lids and the edges, and the holes are holes that allow air-cooled air to pass through. Insert the stator yoke between the front lid and the rear lid, and keep the center of the rotating shaft in place, and pass a long bolt through the bolt from the front lid to the rear lid. A caseless generator with a lid and stator yoke fixed, or a screw thread made in either hole of the bolt hole material attached to the front and rear lids, and a bolt and nut bolted to fix the lid and stator yoke And The generator with a spring is made of a thin iron material, and the case at the position where the stator yoke is fixed is pressed to make the elongated part in the direction of the length of the rotating shaft, and the stator part is processed inside the protruding part. A case where the length of the protruding part that is fixed is made longer than the stator yoke length to improve air permeability, and a long and narrow hole is made in the case part directly above the rotor other than the protruding part to reduce air cooling and eddy current. The bearing case and short edges are attached to the inside of the front and rear lids, and steps are formed at both ends of the front and rear lid edges and the case. Insert and fix the rotation shaft center position, drill some bolt holes inside the front and rear lid edges, and pass the bolts from the outside of the lid to the inside of the front lid edge and the side of the case protruding part to the outside of the rear lid edge. The front and rear lids and the case were fixed by putting out the bolts and tightening the nuts, and the fixed legs of the generator without case were the legs that were attached in parallel and horizontally to the edges of the front and rear lids, with the legs attached The generator is a caseless generator with a hole on the upper side of the rear lid edge that leads out the copper wire, and the legs of the generator with case are slightly out of the outer periphery of the case. The fixing bolt hole material was placed and welded so that it was parallel and horizontal, and the leg was fixed so that a gap of several millimeters could be formed under the case when the legged case was placed on a flat surface. The generator is with a case with the case side on the bottom and a hole to lead out the copper wire on the upper side of the back cover. If not press working, press the shorter rectangular rectangular pipe in the vertical direction. A case with improved ventilation by welding and fixing to the position To drive a generator made of iron or aluminum for the rear lid with an engine or motor, the generator is directly connected to the drive to generate electricity, or the generator is combined with the drive and transmission to generate power. A generator with a large number is directly connected, and a generator with a small number of rotor poles is combined with a generator by a drive and a transmission to increase the rotation speed and increase the electromotive force voltage.

If there are an even number of coils that are separated from the non-adsorptive slot power generation coil, the multi-winding power generation coil is divided into half of the outer coil and the inner coil, and if it is an odd number, the outside of the multi-winding power generation coil It is a two-to-one ratio with two coils and two inner coils, or two series with two outer coils and two inner coils. The distributed winding three-phase non-adsorptive slot generator coil is divided into two coils for the outer coil of the quadruple non-adsorptive slot generator coil using eight slots and the inner coil is separated from the two coils. Non-adsorptive slots separated into two lines with the outer coil of the double winding non-adsorptive slot power generation coil using one slot and the inner coil as one coil. It was conductive coil disposed

The advantage of the two series separation coils is that they are in the same direction, with four quadruple-winding power generation coils in one place and a double-winding outer coil as a right-handed coil in series wiring, and a double-winding inner coil as a right-handed coil in series wiring. When single-phase output is performed simultaneously from the outer coil and the inner coil separated into two series of coils, the output excitation generated in the two separated coils is attracted inside the stator yoke, and the non-adsorptive slot power generation coil of the stator yoke The output excitation disappears from the inner rotor side surface, and a separate coil that utilizes the fact that the iron rod is not attracted by the magnetic force even if it contacts the inside of the coil and the vicinity of the coil, the output excitation enters the stator yoke from the surface. The output excitation has disappeared from the rotor, and the length of the rotor pole in the rotation direction is set to the length of the rotation direction of the central perforated fan magnet so as to be within the inner coil width, or the rotor The inner coil arrangement width that is wider than the rotation direction length of the pole is described as an example, the number of non-adsorptive slots of the 4-pole rotor is 1 to 48, and the length of the 1st pole of the rotor is Arrangement of the non-adsorptive slot power generation coil separated into two series with the rotor No. 1 pole rotor having the length of the number of non-adsorptive slots from 1 to 12, which is a quarter of the number of adsorption slots, No. 2 and No. 2 non-adsorptive slots are installed in No. 15 and No. 16 non-adsorptive slots. A coil with a width that has a double-winding generator coil in the slot

The output wiring of the non-adsorptive slot generator coil separated into two lines is a single-phase output from the left and right copper wires of the outer non-adsorptive slot generator coil, and the single-phase output from the left and right copper wires of the inner non-adsorptive slot generator coil. Inner same direction right side copper wires are connected to each other, left side copper wires are connected to each other, and the single phase output line may be changed from four single phase output lines to two single phase output lines. The distributed winding three-phase non-adsorptive slot power generation coil is separated from each line of the same direction winding coil in which the outer coil of the three-phase wire such as U line, V line, and W line is connected in series and the inner coil is also connected in series. The number of phase output lines may be six, or the same unidirectional single-phase output lines may be connected to form three single-phase output lines. The same directional output lines of the three single-phase output lines may be neutral points. When three wires are connected to form a three-phase output with star connection, the voltage of the electromotive force also increases. However, since the output excitation is generated in the coil connected to the neutral point, it feels a little load on the rotation, but it will rotate with low torque power as a whole, so it will be a star connection generator that has no problem or delta connection Since the three-phase output line generates output excitation, it feels a load on the rotation and the voltage of the electromotive force is a little low, but the generator is designed to respond by raising the rotation a little, and the outer coil is a star connection and the inner coil is a delta Although it may be connected, basically two series of non-adsorptive slot power generation coils with single-phase output are used, and the advantage of the separation coil is that the output excitation is extinguished, and the coil heat and the heat generation of the stator yoke are within the rating. If it is output, even if the generator is operated for 1 hour, it should be a level that feels a little heat

Arrangement of 2-pole rotor and multi-winding power generation coil (Fig. 1), 2-pole rotor is N-pole and S-pole, N-pole and N-pole rotor or S-pole and S-pole rotor, Is a non-adsorptive slot arranged parallel to the rotation axis, or a non-adsorptive slot arranged diagonally, and a power generation coil is wound three times, four times, five times, A multi-winding power generation coil having multiple windings, a multi-winding power generation coil disposed at a position where two rotor poles simultaneously pass, and a four-left-handed power generation coil in the first to 24th non-adsorption slots with the same disposition position The left-handed power generation in the non-adsorption slots of No. 2, No. 3, No. 4, No. 5, No. 8, No. 9, No. 10, and No. 11 A coil is installed and the right copper wire at the end of winding is the neutral point. The left-hand copper coil is placed in the non-adsorptive slots of No. 14, No. 15, No. 16, No. 17, No. 20, No. 21, No. 22, No. 23 and No. The non-adsorptive slot is not provided in the number part that is not used, and the non-adsorptive slot power generation coil wiring is the rotor pole N-pole and S-pole rotor and non-adsorption slot power generation coil wiring The two single-phase outputs from the four-winding power generation coil, or the neutral point of the U1 power generation coil and the neutral point of the U2 power generation coil are connected in parallel to form U1 and U2 A single-phase output from each output line, and the rotor poles of N pole and N pole, or S pole and S pole, and the non-adsorptive slot generator coil wiring are individually connected to two places from the quadruple winding generator coil. Single phase output or neutral point of U1 generator coil and U2 generator Connect the coil output line to make a series wiring, and the U1 output line and the U2 neutral point have a single-phase output in one place. A generator with a thick lead-out copper wire, a lead-out copper wire wired to an operation panel made outside the stator yoke, and a single-phase leakage prevention switch wired from an ammeter to a 100V plug, and power generation using the engine as power The operation panel was equipped with an engine ON / OFF switch, water temperature gauge, oil gauge, and operating time integration meter.

The non-adsorptive slot in which the two-pole rotor and the two-phase non-adsorptive slot power generation coil (FIG. 2) are arranged is the non-adsorptive slot arranged in parallel to the rotation axis, or the non-adsorptive arranged in the oblique direction. The winding coil is arranged in the non-adsorption slot numbered 1 to 32 in the clockwise direction, and the double-winding power generation coil is placed on the left side of the U1 coil, with the copper wire as the output wire, and from 1 and 2 to 7 and 8 A left-handed coil is placed in the non-adsorption slot of No. 2 and the right end copper wire is placed at the neutral point, and the U2 coil left-hand winding start copper wire is used as an output line to the non-adsorption slots of No. 9 and 10 to No. 15 and 16 A left-handed coil is placed in the non-adsorptive slots of No.17, No.18 to No.23 and No.24, with a left-handed coil installed and the right-hand copper wire at the end of winding as the neutral point and the U3 coil starting winding copper wire as the output line. Right end of winding copper wire is neutral point, U4 coil starts winding Using copper wire as the output wire, left-handed power generation coils are installed in the non-adsorption slots of No. 25, No. 26 to No. 31, and No. 32. No. 5 and No. 6 to No. 11 and No. 12 non-adsorptive slots are provided with left-handed coils, the right-hand winding end copper wire is the neutral point, and the V2 coil left-handed starting copper wire is the output wire No. 13 and 14 No. 19 and No. 20 non-adsorptive slots are provided with left-handed coils, the right-hand winding end copper wire is the neutral point, the V3 left-hand winding starting copper wire is the output wire, and 21st and 22nd to 27th and 28th A left-handed coil is placed in the non-adsorptive slot of the coil, and the right end copper wire is placed at the neutral point at the end of winding. Install a coil and set the right-hand winding end copper wire to the neutral point. In addition, the power generation coil wiring in which the rotor poles are the N pole and the S pole are individually set to a single-phase output from the output line of the double winding power generation coil and the neutral point, or the U power generation coil and the V power generation coil. The neutral points of U1 coil and U3 coil, U2 coil and U4 coil, V1 coil and V3 coil, V2 coil and V4 coil that pass simultaneously are connected to each other in parallel, and 4 single-phase outputs are output from each output line. Generator coil wiring with rotor poles of N and N poles, or S and S poles, either single-phase output from double winding coils or neutrality of coils passing simultaneously Connect the point and the output line in series and set each output line and four single-phase outputs from the neutral point, or the U-coil # 1, 3 and U-coil # 2, # 4, V The neutral points of No. 1 and No. 3, No. 2, No. 2 and No. 4 of coil were connected to make parallel wiring, and the generated voltage was raised. The coil and V coil have a single-phase output at two locations, and the U-coil and V-coil output lines that are output in the same direction at two locations are connected to form a single-phase output at one location. In addition, each output line has a lead-free copper wire attached to the copper wire of the non-adsorptive slot power generation coil, and a single-phase leakage prevention switch input terminal arranged on the operation panel made outside the stator yoke. The generator was wired from the output terminal to the ammeter and 100V plug, and this wiring could also be used for a two-phase non-adsorptive slot generator coil generator with a 4-pole rotor.

The non-adsorptive slot in which the two-pole rotor and the three-phase non-adsorptive slot power generation coil are arranged is the non-adsorptive slot arranged in parallel to the rotation axis, or the non-adsorptive slot arranged obliquely, and the right Arrangement of the triple winding power generation coil in the non-adsorption slots No. 1 to No. 36 of the looping number is as follows. The first copper winding starts the left side copper wire as the output line, No. 1, No. 2, No. 3, No. 16, No. 17, A left-handed coil is placed in the 18th non-adsorptive slot and the right end copper wire is wound at the neutral point, and the left side copper wire at the start of winding the U2th coil is used as the output line. 19th, 20th, 21st, 34th, 35th A left-handed coil is placed in the 36th non-adsorptive slot and the right end copper wire is wound at the neutral point, the left side copper wire starts winding the V1 coil, and the left side copper wire is the output wire. Place a left-handed coil in No. 30 suction-free slot and wind it Instead, the right-hand copper wire is the neutral point, the V2 coil starts winding, the left-hand copper wire is the output wire, and the left-hand coil is placed in the non-adsorptive slots of No. 31, 32, 33, No. 10, No. 11, and No. 12. End the right copper wire at the neutral point and start winding the W1 coil. Use the left copper wire as the output wire and place the left-hand coil in the non-adsorption slots 25, 26, 27, 4, 5, 6 At the end, the right copper wire is the neutral point, and the W2 coil is wound. The left copper wire is the output wire, and the left-hand coil is placed in the non-adsorption slots of Nos. 7, 8, 9, 22, 22, 23, and 24. At the end, the right copper wire is set as the neutral point, and the coil wiring of the stator yoke with the rotor poles as N and S poles is individually set to single-phase output from the triple winding power generation coil, or each UVW three-phase power generation Connect the coil neutral points 1 and 2 of the coil passing through the coil at the same time The parallel wiring has three single-phase outputs, or the three neutral points of the UVW wires wired in parallel are bundled to form a three-phase output, and the rotor poles are N poles and N poles. Alternatively, the coil wiring of the stator yoke with the S and S poles is individually set to single-phase output from the triple winding power generation coil, or the neutral point of the coil passing simultaneously and the output line are connected in series as UVW output lines. A single-phase output from the neutral point, or three neutral points of each of the UVW coils connected in series are bundled to form a stay connection or a delta connection, and the output line is a stator yoke that protrudes slightly from the non-sucking slot power generation coil Attach a lead-out copper wire that prevents leakage at the rear position, wire the lead-out copper wire to the input terminal of the single-phase leakage prevention switch located on the operation panel outside the stator yoke, and plug the ammeter and 100V from the output terminal. Power generation wired to What we did

The non-adsorptive slot in which the 4-pole rotor and the three-phase double-winding power generation coil (FIG. 3) are arranged is the non-adsorptive slot arranged in parallel to the rotation axis, or is arranged diagonally to the upper right from the front side of the stator yoke. The non-adsorptive slot is installed, and the single winding coil of the non-adsorptive slot numbered from 1 to 24 in the clockwise direction and the double-winding generator coil in the non-adsorptive slot of number 1 to 48 have the same coil arrangement. As for the arrangement of the double-winding power generation coil series wiring, the left-handed power generation coil is disposed in the non-adsorptive slots of No. 1, No. 2, No. 11, and No. 12 with the left copper wire as the output line at the start of winding No. 1 coil and the winding is finished. The right-hand copper wire is connected to the left-hand copper wire at the start of winding the U3 coil, the left-handed coil is disposed in the non-adsorptive slots of 25th, 26th, 35th, and 36th. No. coil winding left side copper The left-handed power generation coil is arranged in the non-adsorption slots Nos. 13 and 14 to 23 and 24, and the right end copper wire is wound with the U4 coil and the left side copper wire is connected to No. 37 and No. 38. Left-handed coils are placed in the 47 and 48 non-adsorptive slots, and the right end copper wire is the U2 neutral point, the first left side copper wire is the output wire, and the 9th and 10th through the 19th and 20th. A left-handed coil is installed in the non-adsorptive slot, the right end copper wire is wound, the V3 coil starts, the left copper wire is connected, and left-handed coils are arranged in the non-adsorptive slots of Nos. 33 and 34 to 43 and 44. Set the winding end to the right copper wire as the V1 neutral point, start winding the V2 coil, the left copper wire as the output wire, and place the left-handed coil in the non-adsorptive slots from No. 21, No. 22, No. 31, and No. 32. End right copper wire V4 The left winding coil is connected to the left copper wire at the beginning of winding, and left-handed coils are arranged in the non-adsorption slots of No. 45, No. 46 to No. 7 and No. 8, and the right-side copper wire is V2 neutral point. The left-handed power generation coil is arranged in the non-adsorption slots of Nos. 17 and 18 to Nos. 27 and 28 with the wire as the output line, and the right end copper wire is connected to the left side copper wire starting the No. 3 coil winding and No. 41 and No. 42 are connected. No. 3 and No. 4 non-adsorptive slots are provided with left-handed coils and the right end copper wire is the W1 neutral point, the W2 coil start and the left-hand copper wire is the output line, 29th, 30th to 39th A left-handed power generation coil is arranged in the No. 40 non-adsorptive slot, the right end copper wire is wound to the W4 No. coil start, the left side copper wire is connected, and the No. 5 and No. 15 to No. 16 and No. 16 No Adsorption slots are provided with the left-handed coil. W2 neutral point at the end of winding and right side copper wire The output wiring of each UVW line should be 6 single-phase outputs from the neutral line at the end of winding and the output line that is connected in series, or the first and second serial wiring of each UVW phase Connected neutral points to make parallel wiring, and each left-hand winding starts to output three single-phase outputs from the output copper wire, or the same direction coil output copper wire that is considered as three single-phase outputs in the middle As a sex point, connect the three wires in a bundle and output from the output wire in the same direction on the opposite side as a star connection or delta connection. The lead copper wire is a slightly thick lead copper wire that is prevented from leaking as a copper wire to be pulled out of the stator yoke, and the lead copper wire is a three-phase leakage prevention switch input terminal arranged on the operation panel made outside the stator yoke Wire the output terminal to an ammeter, 100 Insert, it was wired to the three-phase 200V terminal generator

The non-adsorptive slot in which the 4-pole rotor and the three-phase triple winding power generation coil are arranged is the non-adsorptive slot arranged in parallel to the rotation axis, or the non-adsorptive slot arranged in the oblique direction is clockwise. The three-phase series wiring of the non-adsorptive slot power generation coil with three windings in the non-adsorptive slots of No. 1 to No. 36 is as follows: The U1 coil starts winding and the left copper wire is the output line. The left-handed coil is placed in the 11th and 12th non-adsorptive slots, the winding end right side copper wire is connected to the left side copper wire starting the U2 coil winding, and the 19th, 20th, 21st to 28th, 29th, 30th A left-handed power generation coil is arranged in a non-adsorptive slot, the right end copper wire is the U1 neutral point, the left end copper wire starts winding the V1 coil, and the left copper wire is the output wire. Place a left-handed coil in the non-adsorption slot The right-hand copper wire is connected to the left-hand copper wire at the beginning of the V2 coil, and the left-handed coil is placed in the non-adsorptive slots of Nos. 25, 26, 27, 34, 35, and 36. V1 neutral point, W1 coil winding start copper wire as output line, left winding coil is placed in No.13, No.14, No.15, No.22, No.23 and No.24 non-adsorptive slots and the right end copper wire is wound W2 coil winding start was connected to copper wire and left-handed power generation coil was placed in non-adsorptive slots of No. 31, 32, 33, No. 4, No. 5, and No. 6, and the right end copper wire was made W1 neutral point In addition, the output that uses each coil of UVW as a left-handed series wiring is a single-phase output from the copper wire at the beginning of the output wire winding and the winding end neutral point, or three neutral points at the end of the right-hand winding of the UVW wire Each output line as a star connection or delta connection as a bundle The output wire, which is a stay connection or delta connection, is a slightly thick lead-out copper wire that is prevented from leaking from the non-adsorptive slot power generation coil to the outside of the coil, and the lead-out copper wire is connected to the outside of the stator yoke. The generator is arranged on the operation panel made in the above, wired to the input terminal of the three-phase leakage prevention switch, wired from the output terminal to the ammeter, 100V plug, and three-phase 200V plug.

The non-adsorptive slot in which the 4-pole rotor and the three-phase quadruple-winding power generating coil are arranged is set to the non-adsorptive slot arranged in parallel with the rotation axis, or the non-adsorptive slot arranged obliquely is clockwise. No. 1 to 48 non-adsorptive slots, the winding of the 4-winding coil is U1 coil winding, the left copper wire is the output line, 1st, 2nd, 3rd, 4th to 13th and 14th A left-handed coil is disposed in the 15th and 16th non-adsorptive slots, and the right end copper wire is connected to the left side copper wire by starting the U2 coil winding, and the 25th, 26th, 27th, 28th to 37th, 38th No. 39 and No. 40 non-adsorptive slots are provided with left-handed power generating coils, the right end copper wire is the U1 neutral point, the first V1 coil winding start and the left copper wire is the output line, No. 9, No. 10, and No. 11 No suction slot from No. 12 to No. 21, No. 22, No. 23 and No. 24 A left-handed coil is placed on the wire and the right end copper wire is wound with the V2 coil, and the left side copper wire is connected to the left-hand copper wire. No. 33, 34, 35, 36, 45, 46, 47, 48 A left-handed power generation coil is arranged in the slot, the right end copper wire is set as the V1 neutral point, and the first left side copper wire is output as the W1 coil winding, and the 17th, 18th, 19th, 20th, 29th and 30th No. 31 and No. 32 non-adsorptive slots are provided with a left-handed coil, and the right end copper wire is wound with a W2 coil, and the left side copper wire is connected to the left side copper wire, and then 41, 42, 43, 44, 5 and 6 No. 7 and 8 non-adsorptive slots are provided with left-handed power generating coils and the right end copper wire is set to the W1 neutral point. The output of UVW wire connected in series is the start and end copper wires. 3 single-phase outputs from the wire, or each winding start left copper wire The output line is a three-phase output line that is a star connection or delta connection with the copper wire at the end of the right-hand winding as a neutral point. A copper wire is used, and the coil copper wire and the lead copper wire are connected with a crimp terminal and solder at a position slightly protruding from the power generation coil. The lead wire is made outside the stator yoke with a vinyl tape and glass fiber to prevent leakage. The generator is wired to the input terminal of the three-phase leakage prevention switch arranged on the control panel and wired from the output terminal to the three-phase 200V plug from the ammeter.

The non-adsorptive slot in which the 6-pole rotor and the three-phase double-winding power generating coil (FIG. 4) are arranged is the non-adsorptive slot arranged in parallel to the rotation axis, or the diagonally arranged non-adsorptive slot. No. 1 to 18 non-adsorptive slots in the clockwise direction have single-winding power generating coils and double-spinning power generating coils in No. 1 to 36 non-adsorptive slots. Arrangement of the double-winding power generation coil in the non-adsorptive slot is the end of winding by placing the left-hand coil in the No. 1, No. 2 to No. 7 and No. 8 non-adsorptive slots with the left copper wire as the output line. The right copper wire is connected to the left copper wire at the beginning of the U2 coil winding, the left-handed power generation coil is disposed in the non-adsorptive slots of No. 13, No. 14 to No. 19, and No. 20, and the winding is completed. Connected 25th, 26th to 31st , The left-handed coil is placed in the 32nd non-adsorptive slot, the winding end right copper wire is the U1 neutral point, the winding of the V1 coil starts and the left copper wire is the output wire, 5th, 6th to 11th, 12th A left-handed coil is placed in a non-adsorptive slot, the winding ends and the right-hand copper wire starts to wind with a V2 coil, and is connected to the left-hand copper wire. End right-hand copper wire is connected to copper wire at the beginning of V3 coil, left-handed coil is placed in No. 29, 30 to 35, 36 non-adsorptive slots, and the right end copper wire is V1 neutral point, W1 The left-handed copper wire is used as the output wire, and the left-handed coil is placed in the 9th, 10th to 15th, and 16th non-adsorptive slots. , 22 to 27 and 28 A left-handed coil is placed in the non-adsorptive slot and the winding is finished. The right-hand copper wire is connected to the beginning of the W3 coil and connected to the copper wire, and the left-handed coil is placed in the 33rd, 34th to 3rd and 4th non-sucking slots. The right copper wire is the W1 neutral point, and the output of UVW wires connected in series is a single-phase output from the winding start copper wire and winding end copper wire at three locations, or each winding start left copper wire is the output line A three-phase output line with a star connection or a delta connection with a copper wire as the neutral point at the end of the right-hand winding, and the output line is a slightly thick lead that is prevented from leaking from the non-adsorptive slot generator coil to the copper wire The copper wire is connected to the front side of the stator yoke or slightly out of the power generating coil on the stator yoke, and the coil copper wire and lead-out copper wire are connected with crimp terminals and solder, and the connection part is prevented from leakage by vinyl tape and glass fiber. Drawer It has a line of stator yoke outside crafted control panel three-phase leakage prevention switch input generator that is wired to the terminal to be routed from the ammeter from the three-phase output terminals to the 100V plug from down transformer from a three-phase 200V plug

The non-adsorptive slot in which the 6-pole rotor and the three-phase double-winding power generation coil are arranged is an unadsorbed slot arranged in parallel to the rotation axis, or the non-adsorptive slot arranged obliquely is a clockwise number No. 1 to No. 72 non-adsorptive slots are installed with a double-winding power generation coil. U1 No. coil winding starts with the left copper wire as the output line, and No. 1, No. 2 to No. 11 and No. 12 no-adsorption slots are left-handed Coil is placed and winding end right copper wire is connected to left copper wire starting U3 coil winding and left winding power coil is placed in No. 25, No. 26 to No. 35 and No. 36 suction slots and winding right side copper wire is connected The U5 coil winding is connected to the copper wire and the left-handed coil is placed in the No. 49, 50 to 59, 60 non-adsorptive slots, the winding end right copper wire is the U1 neutral point, and the U2 coil winding starts to the left copper Lines 13 and 14 as output lines No. 23 and No. 24 non-adsorptive slots are provided with a left-handed coil, and the right end copper wire is connected to the left side copper wire starting with U4 coil winding and left-handed to No. 37, 38 to 47, and No. 48 non-adsorptive slots. The generator coil is placed and the winding end right copper wire is connected to the U6 coil winding start copper wire, the left winding coil is placed in the No. 61, 62 to 71 and 72 non-adsorptive slots, and the winding end right copper wire is connected to the U2 coil. Set the neutral point, start winding the V1 coil, use the left copper wire as the output wire, and place the left-handed coil in the 9th, 10th to 19th, 20th non-adsorptive slots. Connected with copper wire, left-handed generator coil is placed in non-adsorptive slots No. 33, No. 34 to No. 43 and No. 44, and the right end copper wire is wound with V5 coil and connected to the copper wire No. 57, No. 58 to No. 67 No. 68, No adsorption A left-handed coil is placed on the wire and the right-hand copper wire at the end of winding is the V1 neutral point, and the left-hand copper wire is used as the output wire at the start of winding the V2 coil. Coil is placed and winding end right copper wire is connected to left copper wire starting V4 coil winding and left winding power coil is placed in non-adsorption slot of No. 45, No. 46 to No. 55, No. 56 At the beginning of winding the V6 coil, connect the copper wire to the 69th, 70th to 7th and 8th non-adsorptive slots and place the left-handed coil at the winding end right copper wire as the V2 neutral point and start winding the W1 coil The left-hand coil is arranged in the non-adsorption slots of No. 17, 18 to 27, and No. 28 with the wire as the output line, and the winding end right copper wire is connected to the left copper wire starting the W3 coil winding, and No. 41, No. 42 to 51 No. and No. 52 suction-free slot A left-handed coil is installed and the right end copper wire is connected to the beginning of the W5 coil and the left end coil is connected to the 65th, 66th to 3rd and 4th non-adsorptive slots. Set the W1 neutral point, start winding the W2 coil, use the left copper wire as the output wire, place a left-handed coil in the No. 29, 30-39, and 40 non-adsorptive slots and start winding the right-hand copper wire to the W4 coil Connect the left copper wire to the left, 53, 54 to 63, 64 non-adsorptive slots and place the left-handed power generation coil. The left-handed coil is placed in the 15th and 16th non-adsorptive slots, and the right end copper wire is set to the W2 neutral point. The output of the UVW wire odd-numbered and even-numbered coils connected in series Copper wire and end copper wire 6 single-phase outputs, or two-phase three-phase output lines, such as star connection or delta connection with the left-hand copper wire as the output line and the right-hand end copper wire as the neutral point, The output wire is a slightly thick lead-out copper wire that is prevented from leaking from the non-adsorptive slot power generation coil to the copper wire, and the coil copper wire and the lead-out copper wire are connected with a crimp terminal and solder at a position slightly out of the power generation coil. , The lead-out copper wire, which is leakage-prevented with a shrinkable tube, vinyl tape, and glass fiber, is wired from the three-phase output terminal to the three-phase 200 V leakage prevention switch input terminal. The generator is wired to the plug and down transformer and wired from the down transformer to the 100V plug.

  The non-adsorptive slot in which the 6-pole rotor and the three-phase quadruple-winding power generating coil (FIG. 5) are arranged is the non-adsorptive slot arranged in parallel to the rotation axis, or the non-adsorptive slot arranged obliquely. In the non-adsorption slot numbered 1 through 72, the winding of the four-winding coil is routed from No. 1, No. 2, No. 3, No. 4, No. 13 using the left copper wire as the output line. No. 14, No. 15, No. 16 and No. 16 non-adsorptive slots are provided with a left-handed coil, and the winding end right copper wire is connected to the left copper wire starting with U2 coil winding, and No. 25, No. 26, No. 27, No. 28 to No. 37 No. 38, No. 39, No. 40 non-adsorptive slots are provided with left-handed power generating coils, and the right end copper wire is connected to the beginning of U3 coil winding and connected to the copper wire No. 49, No. 50, No. 51, No. 52 to No. 61 No. 62, 63, 64, non-adsorption slot The right copper wire at the end of winding is the U1 neutral point, the winding of the V1 coil is the left copper wire as the output wire, 9, 10, 11, 12 to 21, 22, 23, A left-handed coil is disposed in the No. 24 non-adsorptive slot, and the winding end right copper wire is connected to the left copper wire starting from the V2 coil winding, and the 33rd, 34th, 35th, 36th to 45th, 46th, 47th, A left-handed power generating coil is arranged in the 48th non-adsorptive slot, and the right end copper wire is connected to the copper wire starting the V3 coil winding and connected to the 57th, 58th, 59th, 60th to 69th, 70th, 71st, A left-handed coil is disposed in the 72nd non-adsorptive slot, and the right end copper wire is set as the V1 neutral point, and the left side copper wire is started as the W1 coil winding, and the left side copper wire is used as the output line. No. 30, No. 31, No. 32, left-handed carp in the non-adsorption slot Winding right end copper wire is connected to left side copper wire starting W2 coil winding, and left-handed power generation in non-adsorption slots No. 41, No. 42, No. 43, No. 44 to No. 53, No. 54, No. 55, No. 56 Coil is placed and the right end copper wire is connected to the start of W3 coil winding and the copper wire is connected to the 65th, 66th, 67th, 68th to 5, 6th, 7th, 8th non-adsorptive slots. The right end copper wire at the end of winding is the W1 neutral point, and the output of UVW wires connected in series is a single-phase output at three locations from the winding start copper wire and the winding end copper wire, Three-phase output wire with star connection or delta connection with the left copper wire at the start of winding as the output wire and the copper wire at the right end of winding as the neutral point, and the output wire leaks from the non-adsorptive slot power coil to the copper wire. A slightly thick lead-out copper wire that was prevented from the generator coil Operation panel with coil copper wire and lead copper wire connected with crimp terminal or solder at the protruding position, and lead-out copper wire made of shrink tube, vinyl tape and glass fiber to prevent leakage from outside the stator yoke The generator is wired to the three-phase 200V leakage prevention switch input terminal and wired from the three-phase output terminal to the three-phase 200V plug from the ammeter, and stepped down from 200V to 100V.

  Use each of the non-adsorptive slot power generation coils as described, or separate the power coils that have been wound in double, triple, and quadruple and eliminate the output excitation from the center of the coil. The installed multiple winding non-adsorption slot power generation coil is separated into an outer coil and an inner coil, the outer coil is two coils, the inner coil is one coil, the outer coil is three coils, the inner coil is one coil, or a number close to the same number Non-adsorptive slot generator coil generator that was separated into outer coil and inner coil.

  The generator is a combination of a fan-shaped magnet rotor and a non-adsorptive slot generator coil, and has the advantage of being able to generate power with a low-torque engine or motor.

2-pole rotor and quadruple winding non-adsorptive 24-slot power generation coil 45 degrees to the right 2-pole rotor and 2-phase double winding non-adsorption 32-slot power generation coil 4-pole rotor, double winding non-adsorptive 48-slot power generation coil and U1 coil range 45 degree diagonally right-up development 6-pole rotor, double winding non-adsorption 36-slot power generation coil and U1 coil range 45 degrees to the right 6 pole rotor and 4 winding non-adsorption 72 slot power generation coil 6-pole rotor center hole fan-shaped magnet and fixing bracket layout

A strong permanent magnet is a fan-shaped magnet and a molded fan-shaped magnet is arranged at each pole of the rotor with the same polarity of the fan-shaped magnets of a certain height and thickness facing the coil side. The non-adsorptive slot power generation coil arranged inside was arranged obliquely.

  Fig. 4 shows a generator with a 6-pole rotor and non-adsorptive slot power generation coils Nos. 1 to 36 diagonally arranged in a three-phase output with a star connection, and a 7,5-kW motor with a 6-pole rotor rotated by a delta connection. When 200V is output from the generator and the compressor with 100V power consumption of 15A is operated with the down transformer set to 100V, the power consumption of the motor is 15A, and the power consumption when the motor is idling at the same rotation speed is 10A.

  Wind power generation, hydroelectric power generation, automobile generators, bicycle generators, generators connected to motors driven in factories by pulleys and pulley belts or directly connected to the motor's rear rotating shaft.

DESCRIPTION OF SYMBOLS 1 Stator yoke 2 Non-adsorption slot number 3 Center hole fan-shaped magnet 4 T type power transmission board 5 Stainless steel pipe covered with a rotating shaft 6 Rotating shaft 7 Through bolt hole 8 Winding start output copper wire
9 Neutral point of copper wire at the end of winding 10 Coil number 11 Upward slant 45 degrees non-adsorptive slot power generation coil 12 Rotating shaft center line 13 Protrusion that binds non-adsorptive slots extended before and after the stator yoke with a thread 14 U1 output line 15 U1 neutral point 16 V1 output line 17 V1 neutral point 18 W1 output line 19 W1 neutral point 20 U2 output line 21 U2 neutral point 22 V2 output line 23 V2 neutral point 24 W2 output line 25 W2 center line 26 Front side Bearing 27 Suction and discharge fan 28 Front stainless steel disk and T-type power transmission plate welded portion 29 Repulsive magnetic flux pole 30 T-type power plate magnet pop-out prevention bent portion 31 Through bolt and fixing nut 32 Center hole fan-shaped magnet height 33 Rear side bearing 34 T-type power transmission plate and stainless steel pipe welded portion 35 Fan magnet coil side left and right lower stage and T-type power transmission plate magnet retainer

Claims (2)

  (A) The present invention has a cylindrical structure in which the stator yoke is cylindrical and the inner circumference into which the rotor is inserted is also circular. The non-adsorptive slot is made of stainless steel, aluminum, acrylic plate, PVC resin, glass fiber, rubber, vinyl hose, and slot sheet that are not adsorbed to the magnet. A thin member is cut to a length slightly longer than the stator yoke length to form a U-shaped, U-shaped, round pipe, or elliptical non-adsorptive slot, and the non-adsorptive slot is energized. A slot sheet is provided for the non-energized member and no slot sheet is provided for a member that is not energized. A power generation coil is inserted into a non-adsorptive slot fixed toward the rotor side to form a non-adsorptive slot power generation coil, and the non-adsorptive slot is fixed around the inner circumference of the stator yoke by welding, screwing, and resin rubber glue. Protrusions made before and after the stator yoke after inserting the generator coil, coil end part of the non-adsorptive slot generator coil, non-adsorptive slot generator coil fixed with thread, binding band, and fusion tape The slot opening is covered with a slot sheet that prevents copper wire from jumping out, and the covered slot sheet and the non-adsorptive slot opening are made into a non-adsorptive slot power generation coil bonded with rubber glue and a vinyl resin of hot-melt adhesive material. The generator coil is disposed on the stator yoke. The generator coil is a 2-pole rotor, 4-pole rotor, 6-pole rotor, 6-pole rotor type 3-pole rotor, A multi-winding power generation coil having the same number of rotor poles, a three-phase power generation coil having the number of rotor poles, a two-phase power generation coil, or a one-phase power generation coil. The arrangement relationship between the non-sucking slot and the rotary shaft rotor pole is the non-sucking slot arranged parallel to the circumference of the stator yoke with respect to the rotary shaft rotor installed horizontally. The non-adsorptive slots are arranged in a slanted manner around the inner circumference of the stator yoke, and the non-adsorptive slot power generation coil is arranged at an oblique angle as much as possible from 10 degrees to 45 degrees. The non-adsorptive slot power generation coil arranged as a separation coil is used as a separation coil, and the non-adsorption slot power generation coil or separation coil disposed in parallel or obliquely is rotated and the power generation coil is rotated while the rotor magnetic flux attracts the circumference inside the stator yoke. Across The advantages of the non-adsorptive slot power generation coils arranged in parallel and the fact that the electromotive force is output across the diagonal are easy to manufacture and output as a position far from the rotor where output excitation occurs. The advantage of the non-adsorptive slot power generation coil that is arranged in parallel and diagonally is the diagonal output excitation that appeared in the diagonal non-adsorptive slot power generation coil. As the magnetic flux with the rotor pole parallel to the rotation rotates, the magnetic flux attracts in a small range where the diagonal and parallel intersect, and it is possible to separate the output excitation and the rotor magnetic flux with low torque rotation, and two elongated permanent magnets Tilt one of the two elongated magnets from 45 degrees to 50 degrees when 10 forces are required to separate the permanent magnets that are attracted in parallel with a gap between them The arrangement of the slanted power generation coil utilizing the fact that it can be separated by the force of 5, the output wiring of the non-adsorptive slot power generation coil is individually single-phase output from the power generation coil, or the same polarity of the rotor The generator coils that pass at the same time are connected in series and the coil winding starts with the copper wire as the output wire and the coil winding ends with the copper wire as the neutral point. Three neutral points of copper wire at the end of coil winding are star-connected or delta-connected, and the winding starts from the output line to a three-phase output, and the separation coil separates the non-adsorptive slot power generation coil into an outer coil and an inner coil However, the advantage of the two separated coils is that the stator yoke in the non-adsorptive slot power generation coil can be obtained by simultaneously outputting the AC electromotive force in the same direction to the coil in which the power generation coil is separated into the outer and inner coils. A separate coil that takes advantage of the fact that the output excitation disappears from the surface of the motor side, and the extinction of the output excitation is the output that is attracted by the magnetic field lines of the outer coil and the inner coil inside the stator yoke and is deeply embedded inside the stator yoke. The rotor repulsive magnetic flux reaches the output excitation that is hidden inside the stator yoke, and the rotor is slightly rotated during the output of the electromotive force. To increase the number of coil turns and reduce the rotor diameter by extending the suction slot toward the rotor, the height of the fan-shaped magnet is shortened, or the shape of the fan-shaped magnet on the coil side is straight from the arc circle. Permanent neodymium permanent magnet used as an output rotor on the inner side of the stator yoke and on the outer side of the rotor, and the rotor with the magnetic force attracted by the rotor magnetic flux adjusted. The magnet rotor is a fan with a central hole, and the rotor is designed to push the repulsive magnetic flux toward the generator coil, and the connecting wires of each generator coil are individually connected, or another coil is connected from the beginning of coil winding. It is a series wiring of coils without continuous connection until the end of winding, and the drawn copper wire that pulls the copper wire out of the stator yoke is a little drawn from the coil copper wire and the lead copper wire that is a little thick at the position where it is out of the generator coil Single-phase or three-phase leakage prevention of operation panel with lead-out copper wire placed on the side of the generator or on the back lid of the connection section, with shrink tube, vinyl tape, fusion tape, glass fiber preventing leakage Connect to the input terminal of the machine and rectify from the output terminal to direct current or keep the alternating current as a voltmeter, each output terminal or a generator that is stepped down and wired to a 100V plug, and the generator is case-free It should be a non-adsorptive slot generator coil generator with a case or generator with case (A) The disposition of the non-adsorptive slot power generation coil of each rotor and stator yoke according to claim 1 is described, and the disposition of the 2-pole rotor and the multi-winding power generation coil is as follows. Or N-pole and N-pole rotors or S-pole and S-pole rotors, and non-adsorptive slots arranged in parallel to the rotation axis, or diagonally arranged non-adsorptive A multi-winding power generating coil in which a multi-winding power generating coil having three, four, five, and six windings in a non-adsorbing slot as a slot is disposed at a position where two rotor poles pass simultaneously. The arrangement position is the same, and the description of the arrangement of the quadruple left-handed power generation coils in the non-adsorption slots No. 1 to No. 24 is described. No.5 to No.8, No.9, No.10 and No.11 A left-handed power generation coil is arranged in the landing slot, the right end copper wire is set to the neutral point, the U2 power generation coil starts winding, and the left side copper wire output wire is set as the 14th, 15th, 16th, 17th to 20th and 21st. No. 22 and No. 23 non-adsorptive slots are provided with left-handed power generation coils and the right end copper wire is set as a neutral point. As for the wiring of the coil, the rotor with the N pole and the S pole of the rotor pole and the wiring of the non-adsorptive slot power generation coil are individually provided with two single-phase outputs from the U1 and U2 power generation coils of the quadruple winding power generation coil. Or, connect the neutral point of the U1 power generation coil and the neutral point of the U2 power generation coil to make parallel wiring, and make single-phase output from the output lines of U1 and U2, and the rotor poles are N pole and N pole, Or the rotor made into the S pole and the S pole and the non-adsorption slot The wiring of the generator coil is individually set to two single-phase outputs from the quadruple generator coil, or the neutral point of the U1 generator coil and the output line of the U2 generator coil are connected in series to make the U1 output. A single-phase output from the neutral point of the wire and the U2 neutral point, a slightly thick lead-out copper wire with a little leakage prevention attached to the copper wire slightly out of the non-adsorptive slot power generation coil, and the lead-out copper wire as the stator yoke The generator is wired to the operation panel made outside and wired from the ammeter to the 100V plug from the single-phase leakage prevention switch. (C) A 2-pole rotor and a 2-phase non-adsorptive slot power generation coil are provided. The non-adsorption slot is a non-adsorption slot arranged parallel to the rotation axis, or a non-adsorption slot arranged obliquely, and is wound around the non-adsorption slots numbered 1 to 32 in the clockwise direction. The arrangement of the generator coil is U The left-hand winding of the No. 1 coil is the output wire and the left-hand winding coil is placed in the No. 1 and No. 2 to No. 7 and No. 8 non-adsorptive slots. The first copper wire is the output wire, the left-handed coil is placed in the 9th, 10th, 15th and 16th non-adsorptive slots, the right-hand copper wire at the end of winding is the neutral point, and the U3th coil winding start is the output wire. No. 17 and No. 18 to No. 23 and No. 24 non-adsorptive slots are provided with left-handed power generation coils, the right-hand winding end copper wire is the neutral point, U4 coil winding start copper wire is the output wire, and from No. 25 and No. 26 The left-handed coil is installed in the 31st and 32nd non-adsorptive slots, the right-hand winding end copper wire is the neutral point, the V1 left-hand winding start copper wire is the output wire, and the 5th and 6th to the 11th and 12th A left-handed coil is installed in the non-adsorbing slot of the right-handed copper wire Neutral point, V2 coil left winding start copper wire as output line, left winding coil is placed in No. 13 and 14 to 19 and 20 non-adsorption slots, right winding end copper wire is neutral point, V3 The left-hand winding coil is the output wire and the left-hand winding coil is placed in the No. 21 and 22 to 27 and 28 non-adsorptive slots. As the output wire, left-handed coils were placed in the non-adsorptive slots No. 29, No. 30, No. 3, and No. 4, and the right-handed end copper wire was the neutral point. The generator coil wirings are individually set to single-phase output from the output line and neutral point of the double winding coil, or the U1 coil, the U3 coil, and the U2 coil that pass through the U generator coil and the V generator coil simultaneously. U4 coil, V1 coil and V3 coil, V2 coil A generator coil in which the neutral points of the V4 coil are connected to each other in parallel wiring, and the single-phase output from each output line is set to four output lines, and the rotor poles are N poles and N poles, or S poles and S poles. The wiring is individually set to single-phase output from the double-winding power generation coil, or the neutral point and output line of the coil that passes at the same time are connected in series, and each output line and neutral point are set to four single-phase outputs. Or, connect the neutral points of U-coil # 1, # 3, # 2, # 4, V-coil # 1, # 3, # 2, # 4 of U-coil connected in series to increase the generated voltage by connecting them in parallel. The U-coil and V-coil have two single-phase outputs, and the two U-coil and V-coil output lines connected in the same direction are connected to one single-phase output. Each output line is attached to the copper wire of the non-adsorptive slot power generation coil with a lead-out copper wire preventing leakage, and the lead-out copper wire is connected to the stator arm. Wiring from the input terminal to the single-phase leakage prevention switch input terminal arranged on the control panel made outside the cable, the generator is wired from the output terminal to the ammeter and 100V plug, and this wiring is a two-phase of a 4-pole rotor. (D) A non-adsorptive slot in which a non-adsorptive slot for arranging a four-pole rotor and a three-phase double winding generator coil is arranged in parallel to the rotation axis. Or a non-adsorptive slot disposed diagonally to the upper right from the front side of the stator yoke, and a single winding coil of non-adsorptive slots numbered 1 to 24 in the clockwise direction and 1st to 48th non-adsorptive slots. Since there is a double-winding power generation coil and the coil arrangement is the same, the double-winding power generation coil series wiring is arranged from No. 1 and No. 2 to No. 11 and No. 12 with the left copper wire as the output line. No adsorption slot A left-handed coil is placed on the left end of the winding and the right-hand copper wire is wound on the U3 coil, the left-hand copper wire is connected, and left-handed coils are placed in the No. 25, 26, 35 and 36 non-adsorptive slots. The copper wire is the U1 neutral point, the U2 coil starts winding the left copper wire as the output wire, the left-handed coil is placed in the No. 13 and 14 through 23 and 24 non-adsorptive slots, Start winding U4 coil Connect to left copper wire, place left-handed coil in No. 37 and 38 to 47 and 48 non-adsorptive slots, end winding right side copper wire as U2 neutral point, start winding V1 coil The left copper wire is used as the output wire, the left-handed coil is placed in the 9th, 10th, 19th and 20th non-adsorptive slots. 34th to 43rd and 44th A left-handed coil is installed in the non-adsorptive slot, the winding end right copper wire is the V1 neutral point, the V2 coil starts winding the left-hand copper wire is the output line, and from the 21st and 22nd to the 31st and 32nd nonadsorptive slots A left-handed power generation coil is installed and the right end copper wire is connected to the left copper wire at the start of winding the V4 coil, and the left-hand coil is placed in the non-adsorption slots of Nos. 45, 46 to 7 and 8, and the right end copper The wire is the V2 neutral point, the winding of the W1 coil starts and the left copper wire is the output wire, the left-handed generator coil is placed in the non-adsorptive slots of the 17th, 18th, 27th and 28th The first coil winding is connected to the left copper wire, the left winding coil is arranged in the No. 41 and 42 to No. 3 and 4 non-adsorptive slots, the winding end right copper wire is the W1 neutral point, and the W2 coil winding starts on the left side. Use copper wire as the output wire, 29 and 3 A left-handed coil is placed in the non-adsorption slots from No. 0 to 39 and No. 40, and the right end copper wire is connected to the left side copper wire starting from the No. 4 coil winding, and No. 5 and No. 6 to No. 15 and No. 16 The left-handed coil is placed in the suction slot and the right-hand copper wire at the end of winding is set to the W2 neutral point. The output wiring of each UVW line is 6 points from the output line and the neutral point at the end of winding. Either single-phase output, or the neutral points of the UVW phases 1 and 2 connected in series are connected in parallel to form a single-phase output at three locations from the output copper wire at the beginning of each left winding. The coil output copper wire in the same direction, which is the single-phase output of the place, is connected to a bundle with three neutral wires, and the star connection or the delta connection that outputs from the output signal in the same direction on the opposite side, The output wire is connected to the lead-out copper wire at a point slightly out of the non-adsorptive slot generator coil. The lead-out copper wire is a slightly thick lead-out copper wire that prevents leakage as a copper wire that pulls out of the stator yoke, and the lead-out copper wire extends to the three-phase leakage prevention switch input terminal arranged on the operation panel made outside the stator yoke The generator is wired and connected from the output terminal to an ammeter, 100V plug, and a three-phase 200V terminal. (E) A non-adsorptive slot in which a four-pole rotor and a three-phase triple winding generator coil are arranged The non-adsorptive slots arranged in parallel with each other, or the non-adsorptive slots arranged obliquely are wound in the clockwise direction and the three-phases of the non-adsorptive slot generator coil are wound around the No. 1 to 36 non-adsorptive slots. For the serial wiring, the left-hand copper wire is placed in the non-adsorptive slots of No. 1, No. 2, No. 3, No. 10, No. 11, and No. 12, with the left copper wire at the beginning of winding of the U1 coil as the output line. U2 The left-handed coil is placed in the 19th, 20th, 21st, 28th, 28th, 29th, and 30th non-adsorptive slots and the right end copper wire is set as the U1 neutral point. V1 coil winding starts with the left copper wire as the output line, left winding coil is placed in the non-adsorptive slots of Nos. 7, 8, 9 through 16, 16, 17 and 18 Connected with copper wire, left-handed power generating coil is placed in No. 25, 26, 27, 34, 35, and 36 non-adsorptive slots, winding right end copper wire is V1 neutral point, W1 coil winding starts The copper wire is used as the output wire, and the left-handed coil is disposed in the non-adsorptive slots of Nos. 13, 14, 15 to 22, 22, 23, and 24. No., No. 32, No. 33 to No. 4, No. 5, and No. 6 The left-handed power generation coil is installed in the non-adsorptive slot, and the right-hand copper wire at the end of winding is set as the W1 neutral point. Single-phase output from copper wire, or three-wire bundle of neutral points at the end of right-hand winding of UVW wire, star connection or delta connection, output from each output line, stay connection or delta connection output line Is a slightly thick lead copper wire that is prevented from leaking to the copper wire drawn out from the non-adsorptive slot power generation coil, and the three-phase leakage current that is placed on the operation panel made outside the stator yoke. (1) A four-pole rotor and a three-phase quadruple-winding generator coil, wired to the prevention switch input terminal and wired from the output terminal to the ammeter, 100V plug, and three-phase 200V plug The non-adsorptive slots to be arranged are non-adsorptive slots arranged in parallel to the rotation axis, or the non-adsorptive slots arranged obliquely are assigned to the non-adsorptive slots numbered 1 to 48 in the clockwise direction. The wiring of the heavy winding coil is the left-handed coil in the non-adsorption slots of No. 1, No. 2, No. 3, No. 4, No. 13, No. 14, No. 15, and No. 16 with the left copper wire as the output line. Winding end right copper wire is connected to left copper wire starting U2 coil winding and left-handed power generation in non-adsorptive slots of 25, 26, 27, 28, 37, 38, 39 and 40 The coil is installed and the right copper wire at the end of winding is the U1 neutral point, the V1 coil starts winding the left copper wire is the output wire, and the 9th, 10th, 11th, 12th to 21st, 22nd, 23rd The left-handed coil is placed in the No. 24 non-adsorption slot and the winding ends Start winding the right copper wire with the V2 coil and connect the left copper wire to the left copper coil in the non-adsorption slots No. 33, 34, 35, 36 to 45, 46, 47 and 48 The end right copper wire is V1 neutral point, W1 coil winding start left copper wire is output wire, 17th, 18th, 19th, 20th to 29th, 30th, 31st and 32nd non-adsorptive slots A left-handed coil is placed on the end and the right-hand copper wire is wound on the W2 coil. The left-hand copper wire is connected to the left-hand copper wire, and 41, 42, 43, 44 to 5, 6, 6, 7, and 8 non-adsorptive slots. The left-handed power generation coil is installed in the W1 neutral point at the end of winding and the right-hand side copper wire is connected to the neutral point of the UVW line. Or each winding start left copper wire as output wire and right winding end copper wire neutral The three-phase output line is a star connection or delta connection, and the output line is a slightly thick lead-out copper wire that prevents leakage from the non-adsorptive slot power generation coil to the outside of the coil. Coiled copper wire and lead-out copper wire are connected with crimp terminal and solder, lead-out copper wire is connected to vinyl tape and glass fiber is used to prevent leakage, and three-phase leakage prevention is provided on the operation panel made outside the stator yoke. A generator that is wired to the switch input terminal and connected from the output terminal to the ammeter at 100V and into the three-phase 200V insertion (G) Non-adsorptive slot for arranging the 6-pole rotor and the three-phase double winding coil Are non-adsorptive slots arranged parallel to the rotation axis, or the non-adsorptive slots arranged obliquely are connected to the non-adsorptive slots numbered 1 to 18 in the clockwise direction. There are double winding power generation coils in the non-adsorption slots No. 1 to No. 36 and the coil arrangement position is the same. The left copper wire at the beginning of coil winding is used as the output wire, the left-handed coil is placed in the No. 1, No. 2 to No. 7, and No. 8 suction slots, the winding end right copper wire is connected to the left copper wire at the beginning of U2 coil winding, and No. 13 , No. 14 to No. 19 and No. 20 non-adsorptive slots are provided with left-handed power generating coils, and the right end copper wire is connected to the beginning of U3 coil winding and connected to the copper wire No. 25, No. 26 to No. 31 and No. 32 A left-handed coil is placed in the slot, the right-hand copper wire at the end of winding is the U1 neutral point, and the left-hand copper wire is the output wire at the start of winding the V1 coil. Arrange the winding end right copper Is connected to the left copper wire at the start of V2 coil winding, left-handed power generating coils are disposed in the non-adsorption slots of No. 17, 18 to 23 and 24, and the right end copper wire is connected to the copper wire starting from V3 coil winding 29 No. 30, No. 30 to No. 35, No. 36, left-handed coils are placed in the non-adsorption slots, the right end copper wire is the V1 neutral point, the No.1 and No. 10 windings are the left side copper wire starting the W1 coil winding No. 15 and No. 16 non-adsorptive slots are provided with a left-handed coil, and the right end copper wire is connected to the left copper wire, starting with W2 coil winding, and left-handed to No. 21 and No. 22 to No. 27 and No. 28 non-adsorptive slots. The generator coil is arranged and the winding end right copper wire is connected to the W3 coil winding start copper wire, the left winding coil is arranged in the non-adsorption slots of No. 33, No. 34 to No. 3, and No. 4, and the winding end right copper wire is set to W1. Neutral point and direct UVW line The wired output is a single-phase output at three locations from the winding start copper wire and winding end copper wire, or star connection with each winding start left copper wire as output wire and right winding end copper wire as neutral point Or a three-phase output wire with a delta connection, and the output wire is a slightly thick lead-out copper wire that is prevented from leaking from the non-adsorptive slot power generation coil to the outside of the coil. Operation panel with coil copper wire and lead-out copper wire connected with crimp terminals and solder at a position slightly out of the power generation coil, lead-out copper wire made of vinyl tape and glass fiber to prevent leakage from the stator yoke The generator is wired from the three-phase output terminal to the ammeter, the three-phase 200V terminal or plug, and from the down transformer to the 100V plug. (H) The non-adsorptive slot in which the 6-pole rotor and the three-phase double-winding power generating coil are arranged is the non-adsorptive slot arranged in parallel to the rotation axis, or the non-adsorptive slot arranged obliquely is used. Arrangement of the double-winding generator coil in the non-adsorption slots No. 1 to No. 72 in the clockwise direction is the non-adsorption of No. 1, No. 2 to No. 11 and No. 12 using the left copper wire as the output line at the beginning of winding of the No. 1 coil. A left-handed coil is placed in the slot, the right end copper wire is wound on the U3 coil, the left-hand copper wire is connected to the left-hand copper wire, and left-handed power generating coils are placed in the No. 25, No. 26 to No. 35, No. 36 slots. The copper wire is connected to the copper wire at the beginning of the U5 coil, the left-handed coil is placed in the 49th, 50th to 59th, and 60th non-adsorptive slots, and the right end copper wire is the U1 neutral point, and the U2 coil is wound Beginning with the left copper wire as the output wire No. 13 A left-handed coil is placed in the 14th to 23rd and 24th non-adsorptive slots, and the winding end right copper wire is connected to the left copper wire starting the U4 coil winding and the 37th, 38th to 47th and 48th non-adsorptive slots A left-handed coil is placed on the left end coil, and the right end copper wire is connected to the beginning of the U6 coil and the left end coil is placed in the No. 61, 62 to 71, 72 non-adsorptive slots. Is the U2 neutral point, and the left copper wire is output to the start of winding the V1 coil, the left winding coil is placed in the 9th, 10th to 19th and 20th non-adsorptive slots, and the right end copper wire is wound to the V3 coil First, connect the left-hand copper wire to the 33rd, 34th to 43rd and 44th non-adsorptive slots, and place the left-handed power generation coil, and turn the right-hand copper wire to the V5 coil. No. 67 and 68 A left-handed coil is placed in the suction slot, the winding end right-hand copper wire is the V1 neutral point, the V2-th coil winding starts and the left-hand copper wire is the output wire, and the left-handed winding is placed in the No.21, 22th to 31st, 32nd non-sucking slots. Coil is placed and winding end right copper wire is connected to left copper wire starting V4 coil winding and left winding power coil is placed in non-adsorption slot of No. 45, No. 46 to No. 55, No. 56 V6 coil winding is connected to copper wire and left-handed coil is placed in 69, 70 to 7 and 8 non-adsorptive slots, winding right side copper wire is V2 neutral point, W1 coil winding starts and left side copper The left-hand coil is arranged in the non-adsorption slots of No. 17, 18 to 27, and No. 28 with the wire as the output line, and the winding end right copper wire is connected to the left copper wire starting the W3 coil winding, and No. 41, No. 42 to 51 No. 52 A left-handed power generation coil is arranged on the wire and the right end copper wire is connected to the beginning of the W5 coil and the copper wire is connected to the 65th, 66th to 3rd and 4th non-adsorptive slots. The copper wire is the W1 neutral point, the W2 coil starts winding, the left copper wire is the output wire, the left-handed coil is placed in the 29th, 30th to 39th, and 40th non-adsorptive slots, and the right end copper wire is W4 Connect the left copper wire to the left copper wire at the beginning of coil winding and place the left-handed generator coil in the 53, 54 to 63, 64 non-adsorptive slots and connect the right copper wire at the end of winding to the copper wire to start winding the W6 coil. The left-handed coil is arranged in the 6th to 15th and 16th non-adsorptive slots, and the right end copper wire is set as the W2 neutral point. The output of the UVW line odd-numbered and even-numbered coils connected in series is , Winding start copper wire and winding end Two three-phase output lines with 6 single-phase outputs from the copper wire, or star connection or delta connection with the left copper wire at the beginning of each winding as the output line and the copper wire at the right end as the neutral point The output wire is a slightly thick lead-out copper wire that prevents leakage from the non-adsorptive slot power generation coil to the outside of the coil, and the coil copper wire and lead-out copper wire are crimped with soldering terminals and solder at a position slightly out of the power generation coil. Connect the wiring section to the 200V three-phase leakage prevention switch input terminal on the operation panel made outside the stator yoke with the lead-out copper wire, which is leak-prevented by shrink tube, vinyl tape, and glass fiber. A generator that is wired from the output terminal to the three-phase 200V plug and down transformer and from the down transformer to the 100V plug is installed. (K) A 6-pole rotor and a three-phase quadruple winding coil are installed. The non-adsorptive slots to be arranged are parallel to the rotation axis, or the non-adsorptive slots arranged obliquely are wound around the non-adsorptive slots Nos. 1 to 72 in a clockwise direction. For the wiring of the power generating coil, the left-hand coil is placed in the non-adsorption slots of No. 1, No. 2, No. 3, No. 4, No. 13, No. 14, No. 15, and No. 16 using the left copper wire as the output line. Arrange and wind the right-hand copper wire at the beginning of U2 coil and connect the left-hand copper wire to the left-hand copper coil in the non-adsorption slots 25, 26, 27, 28 to 37, 38, 39, 40 After winding, connect the right-hand copper wire to the beginning of U3 coil winding, and connect the left-handed coil to the No. 49, 50, 51, 52 through 61, 62, 63, 64 non-adsorption slots Arrange the winding end right copper wire as U1 neutral point, Start winding No. 1 and use the left copper wire as the output wire. No. 9, 10, 11, 12 through 21, No. 22, No. 23, No. 24 left-handed coils are placed in the non-adsorptive slots. The wire is connected to the left copper wire at the start of winding the V2 coil, and the left-handed power generation coil is placed in the No. 33, 34, 35, 36 to 45, 46, 47, and 48 non-adsorptive slots. The copper wire is connected to the copper wire at the beginning of the V3 coil, and the left-hand coil is placed in the non-adsorption slots No. 57, No. 58, No. 59, No. 60 to No. 69, No. 70, No. 71, No. 72 Set the wire to the V1 neutral point and start winding the W1 coil. Use the left copper wire as the output wire and turn the left-hand coil into the non-adsorptive slots of Nos. 17, 18, 19, 20 to 29, 30, 31, and 32. Wrapping ends and the right copper wire starts to wind W2 coil Connected to the side copper wire, left winding coil is placed in the non-adsorption slots of No. 41, No. 42, No. 43, No. 44 to No. 53, No. 54, No. 55, No. 56 and the right end copper wire is wound by W3 coil First, connect the left copper coil to the 65, 66, 67, 68 through 5, 6, 6, 7, 8 non-adsorptive slots and connect the copper wire to the beginning. The output of UVW wires connected in series is a single-phase output from the winding start copper wire and winding end copper wire at three locations, or each winding start left copper wire is used as the output wire and right winding end copper wire is used. A three-phase output line with a star connection or delta connection with a neutral point as the neutral point, and a slightly thick lead-out copper wire that prevents leakage from the copper wire drawn out of the coil from the non-adsorptive slot power coil. Crimp terminal with coil copper wire and lead copper wire at the protruding position Connect with solder, and wire the lead-out copper wire, which is leak-proof with shrink tube, vinyl tape, and glass fiber, to the input terminal of the three-phase 200V leakage prevention switch located on the operation panel made outside the stator yoke. A three-phase output terminal to an ammeter, a three-phase 200V plug, a generator that is stepped down from 200V to 100V with a down transformer and wired to a 100V plug, and each described non-adsorptive slot power generation coil is used as described. Or a double winding, triple winding, or quadruple power generation coil as a separation coil, and a wiring in which output excitation is extinguished from the center. Separated into inner coils to increase the number of outer coils, or increase the number of inner coils. Non-adsorptive slot generator coil generator that is supposed to be separated into coils.

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