JP4951099B2 - Back electromotive force and electromotive force generator motor permanent magnet rotor - Google Patents

Description

本発明は、発電と動力モータに関するものです。     The present invention relates to power generation and power motors.

扇形の薄い磁石を、同極同士をステータ ヨークの長さに合わせた枚数を、反発するのを間隔が１ｍｍに成るまで圧縮して１磁極としたロータ。 A rotor having one magnetic pole formed by compressing the number of fan-shaped thin magnets having the same poles matched to the length of the stator yoke until the interval is 1 mm.

特開２００８−１０９８３０JP2008-109830

解決しようとする問題点は、磁石ロータの１磁極を扇形の薄い磁石をステータ ヨークの長さに１ｍｍ間隔で配設すると、磁石を手作業で金具に挿入するのに磁石が反発と引き合う力が邪魔をして、最後に近い枚数の磁石配設は難問で失敗すると磁石が反発力で一瞬に飛び出してしまう、また、隣の磁石極と引き合い吸い付いてしまい動かない、１磁極を薄い扇形磁石をステータ ヨークの長さの中に１ｍｍ間隔で配設した磁極を持つ磁石ロータを、発電モータに使用してインバータ200Ｖの出力をモータの入力線コイルの中性点をスター結線で電流を流すと回転しないデルタ結線では周波数が５０Ｈｚだけ入力線に付けたクランプ電流計が５Ａを表示してモータが回転する、が周波数範囲の上下幅が小さい、周波数範囲以外でモータを回転させると入力線に付けたクランプ電流計が３０Ａに近い数字になるためモータが発熱する。   The problem to be solved is that if one magnetic pole of the magnet rotor is arranged with a fan-shaped thin magnet in the length of the stator yoke at an interval of 1 mm, the magnet attracts the repulsive force to manually insert the magnet into the bracket. If the arrangement of the number of magnets close to the end fails due to difficulties, the magnet will pop out instantly due to the repulsive force, and it will attract and attract the adjacent magnet pole and will not move. When a magnetic rotor with magnetic poles arranged at intervals of 1 mm in the length of the stator yoke is used for the generator motor, the output of the inverter 200V is passed through the neutral point of the motor input line coil with a star connection. In a non-rotating delta connection, the clamp ammeter attached to the input line with a frequency of 50 Hz displays 5A and the motor rotates, but the vertical width of the frequency range is small, and the motor is rotated outside the frequency range. Then, since the clamp ammeter attached to the input line becomes a number close to 30A, the motor generates heat.

ネオジウム永久磁石は、回転方向に扇形で厚さ１０ｍｍ、扇形磁石の上下と左右の中央に６ｍｍの穴を開け、扇形の外周側左右に３ｍｍの深さで１０ｍｍから１５ｍｍの長さのアールを付けた段を作り、左右の段の先端部分を３Ｃの面取りをします、磁石の高さは回転軸上から固定コイルまでの長さを、回転軸上から５ｍｍから１０ｍｍ上がった所からステータ ヨークまでの長さを磁石の高さとし、扇形磁石１枚の固定コイル側の長さは２磁極なら固定コイル回転軸側の内円周の2分の１の円周の長さ、または4分の１の円周の長さから、磁石固定金具の動力伝達板材料の厚み分を差し引いた長さを扇形磁石外周側の長さにするか、または、その長さから１２ｍｍ差し引いた長さとする、４磁極なら固定コイル回転軸側の内円周の４分の１の円周の長さ、または８分の１内円周の長さから、磁石固定金具の動力伝達板材料の厚み分を差し引いた長さを扇形磁石外周側の長さにするか、または、その長さから１２ｍｍ差し引いた長さとする、６磁極なら固定コイル回転軸側の内円周の６分の１の円周の長さ、または12分の１の円周の長さから、磁石固定金具の動力伝達板材料の厚み分を差し引いた長さを扇形磁石の長さにするか、または、その長さから１２ｍｍを差し引いた長さとする、扇形磁石の磁極は外周側と回転軸側とに磁極を持たせる、2磁極ロータは扇形磁石を回転方向に扇形でコイル側にＳ極とＮ極と引き合うように配設、または、扇形磁石4枚をＳ極とＳ極とＮ極とＮ極と同極が1部反発するように同一回転軌道上に配設したのを1磁石リングとします、４磁極ロータは扇形磁石を回転方向に扇形でコイル側にＳ極とＮ極とＳ極とＮ極と引き合うように扇形磁石４枚を同一回転軌道上に配設したのを１磁石リングとします、６磁極ロータは扇形磁石を回転方向に扇形でコイル側にＳ極とＮ極とＳ極とＮ極とＳ極とＮ極と引き合うように扇形磁石６枚を同一回転軌道上に配設したのを１磁石リングとします。   The neodymium permanent magnet is fan-shaped in the direction of rotation and has a thickness of 10 mm. A 6-mm hole is drilled in the top and bottom and the center of the left and right sides of the fan-shaped magnet. 3C chamfering the tip of the left and right steps, the height of the magnet from the rotating shaft to the fixed coil, from 5mm to 10mm above the rotating shaft to the stator yoke The length of the fixed coil side of one sector magnet is the length of one half of the inner circumference of the fixed coil rotating shaft side, or one-fourth of the inner circumference of the fixed coil rotating shaft side. The length obtained by subtracting the thickness of the power transmission plate material of the magnet fixing bracket from the circumferential length of the magnet is the length on the outer periphery side of the sector magnet, or the length obtained by subtracting 12 mm from the length is 4 If it is a magnetic pole, it is a quarter of the inner circumference of the fixed coil rotation axis side The length obtained by subtracting the thickness of the power transmission plate material of the magnet fixing bracket from the length of the circumference or the inner circumference of the eighth is set to the length of the outer periphery of the sector magnet, or the length If the magnetic pole has 6 poles, the length of the inner circumference on the fixed coil rotating shaft side is 1/6 of the circumference, or 1/12 of the circumference of the magnet. The length obtained by subtracting the thickness of the power transmission plate material is the length of the sector magnet, or the length obtained by subtracting 12 mm from the length is the magnetic pole of the sector magnet on the outer peripheral side and the rotating shaft side. The two-pole rotor has a fan-shaped magnet in the direction of rotation and is arranged so that the S-pole and N-pole are attracted to the coil side, or four fan-shaped magnets have S-pole, S-pole, N-pole and N-pole. One magnet ring is arranged on the same rotation track so that one part of the same pole repels. 4 fan-shaped magnets are arranged on the same rotation track so that the S is fan-shaped in the rotation direction and the S-pole, N-pole, S-pole and N-pole are attracted to the coil side. A single magnet ring consists of six fan-shaped magnets arranged on the same rotating track so that the magnets are fan-shaped in the rotational direction and the S-pole, N-pole, S-pole, N-pole, S-pole and N-pole are attracted to the coil side. The

回転軸に配設される、扇形Ｓ磁石極は回転軸の回転方向に扇形で回転軸上に１枚１枚同極同士を垂直に立てて、外周側にＳ極を持つ磁石数枚で組み立てられた磁石ロータのＳ磁石極は回転軸上に平行に配設します、Ｎ極も同じ配設です、磁極の長さはステータ ヨークの長さでその長さの中で磁石を配設する2極発電モータの磁石ロータも回転軸上にＳ，Ｎの磁石極2列を平行に隣同士引き合うように配設、または、Ｓ、Ｓ、Ｎ、Ｎ、と一部反発するように4列を平行に配設、４極発電モータの磁石ロータも回転軸上にＳ、Ｎ、Ｓ、Ｎの磁石極4列を平行に隣同士引き合うように配設、または、Ｓ、Ｓ、Ｎ、Ｎ、Ｓ、Ｓ、Ｎ、Ｎ、と一部反発するように８列を平行に配設、６極発電モータの磁石ロータも回転軸上にＳ、Ｎ、Ｓ、Ｎ、Ｓ、Ｎと平行に磁石極6列が隣同士引き合うように配設する、または、Ｓ、Ｓ、Ｎ、Ｎ、Ｓ、Ｓ、Ｎ、Ｎ、Ｓ、Ｓ、Ｎ、Ｎ、と一部反発するように１２列を平行に配設、配列を多くすることで大型のロータに配設する磁石を小さくして配設出来る、配設した扇形磁石の回転軸上の固定にはステンレス材とステンレスパイプ、または、鉄のパイプとステンレスのボルトとナット、または、鉄のボルトにより固定、ステンレスボルトは全ネジか半分ネジを切ったボルトを使う、または、ステータ ヨーク固定コイルから遠い部分は鉄材を使用しても良い。   The fan-shaped S magnet poles arranged on the rotating shaft are fan-shaped in the direction of rotation of the rotating shaft, and the same poles are placed vertically on the rotating shaft, and assembled with several magnets having S poles on the outer peripheral side. The S magnet pole of the magnet rotor is arranged in parallel on the rotation axis, the N pole is the same arrangement, the length of the magnetic pole is the length of the stator yoke, and the magnet is arranged within that length. The magnet rotor of the two-pole generator motor is also arranged on the rotating shaft so that two rows of S and N magnet poles are drawn next to each other in parallel, or four rows so as to partially repel S, S, N, and N. Are arranged in parallel so that the magnet rotor of the quadrupole power generation motor is also arranged so that four rows of S, N, S, N magnet poles are drawn in parallel on the rotation axis, or S, S, N, N , S, S, N, N, 8 rows are arranged in parallel so as to be partially repelled, and the magnet rotor of the 6-pole power generation motor is also parallel to S, N, S, N, S, N on the rotation axis Arrange 6 stone poles so that they are adjacent to each other, or 12 rows so that some of them repel S, S, N, N, S, S, N, N, S, S, N, N. By arranging in parallel and increasing the arrangement, the magnet placed on the large rotor can be made smaller and fixed on the rotating shaft of the arranged fan-shaped magnet for stainless steel and stainless steel pipe or iron Fix with pipe and stainless steel bolts and nuts, or iron bolts, stainless steel bolts may use full or half-threaded bolts, or steel may be used for parts far from the stator yoke fixing coil.

発電モータの回転軸に磁石を固定する金具には、回転軸を差し込むパイプと、磁石ロータの両端を押さえる左右中央穴あき円盤と、磁極を分ける仕切りを兼ねた動力伝達板と、通しボルトとナットで構成されている、その構成金具の動力伝達板には３種類有り、Ｔ型とＴ型を半分にした、かぎ型、かぎ型とＴ型混合とが有り、Ｔ型動力伝達板にはコイル幅の扇形磁石を使用するため強力な回転力の利点がある、また、かぎ型はコイル幅より小さい寸法の扇形磁石を使用して、動力伝達板の枚数は倍を使用するが、かぎ型とかぎ型の間の空間部分の左右の円盤部分も切り取り左側円盤と右側円盤を貫通させ空気を出入りさせて、固定コイルのスロットを回転駆動中に直接空気冷却が出来る利点がある。Ｔ型動力伝達板の回転軸方向の長さはステータ ヨークの長さに、高さ１０ｍｍで長さ１０ｍｍの段を回転軸側の右側円盤側に作ります、１０ｍｍの段は右側円盤に差し込んで動力伝達板の補強とする、動力伝達板のコイル側に２３ｍｍ幅のアールを付けた部材をステータ ヨークの長さより１５ｍｍ程長くして長い方を動力伝達板の１０ｍｍ段側のコイル側にする、動力伝達板でアールを半々に分けるように中心に溶接しアールの部分を左右磁極の磁石飛び出し防止押さえとする、１５ｍｍ長くした部分はロータ組立て後に回転軸側に９０度曲げて押さえ部の捲れ防止とする。かぎ型動力伝達板の回転軸方向の長さはステータ ヨークの左側の位置より３０ｍｍ長くして、右側ステータ ヨークの定位置から回転軸側に１０ｍｍの長さで高さ１０ｍｍの段を作ります、左側動力伝達板と右側動力伝達板は回転方向から見た方向の左右とする、左側動力伝達板の左側から３０ｍｍの所に左側円盤が差し込まれる３ｍｍの切り口が、回転軸上から左側動力伝達板の半分の高さまで切ってある、１０ｍｍの段は右側円盤に差し込んで動力伝達板の補強とする、その動力伝達板の３ｍｍの切り口のコイル側の左側に１０ｍｍ幅のアールの付けた左側磁石飛び出し防止押さえをステータ ヨークの長さより１５ｍｍ程右側に長くして動力伝達板に溶接します、１５ｍｍ長くした部分はロータ組立て後に回転軸側に９０度まげてから、かぎ型動力伝達板の空気通路側に出ている部分を通路側に曲げて磁石押さえの捲れ防止とする、右側動力伝達板はステータ ヨークの長さに、右側ステータ ヨークの定位置から回転軸側に１０ｍｍの長さで高さ１０ｍｍの段を作る、その動力伝達板の右側に10ｍｍ幅のアールの付けた右側磁石飛び出し防止押さえを、１０ｍｍ段側のコイル側に１５ｍｍ長くして動力伝達板に溶接します、１５ｍｍ長くした部分はロータ組立て後に回転軸側に９０度まげてから、かぎ型動力伝達板の空気通路側に出ている部分を通路側に曲げて磁石押さえの捲れ防止とする、左側動力伝達板の左側円盤側に出した３０ｍｍの空気導入ファン板は、空気導入通路側に角度を付けて固定する、右側動力伝達板の空気導入ファン板は右側円盤の右側動力伝達板の切り込み部に空気導入通路側に角度を付けて固定する、また、動力伝達板の高さは固定コイルの内周側から回転軸に被せたパイプまでの長さとする、Ｔ型動力伝達板の２枚の円盤には扇形磁石中央６ｍｍの穴に合わせた所に穴を開け、長径５ｍｍのボルトの長さはステータ ヨークより１５ｍｍ長いステンレスボルトか鉄のボルトで左側円盤と磁石と右側円盤を固定する位置決めボルト通し穴とボルトとする、また２枚の円盤には中央にパイプが入る穴が開いて、右側円盤の穴には動力伝達板の１０ｍｍの段を差し込む３．５ｍｍの切れ目がパイプの入る穴から上に向けて１０．５ｍｍ切ってある2磁極なら2本、４磁極なら４本、６磁極なら６本をボルト穴から左右に等分して切れ目を作る、また、円盤には固定コイルを空冷する板が左右で４枚溶接してある、かぎ型動力伝達板の２枚の円盤にはボルト穴はＴ型動力伝達板と同じ場所に開けますが、かぎ型動力伝達板の左右の動力伝達板で作る空気導入通路の円盤切り込み部をボルト穴から等分した所の、２極なら２箇所を４極なら４箇所を６極なら６箇所の左右動力伝達板の入る部分を、回転軸上から円盤の固定コイルまでの高さの半分からコイル側を２枚の円盤から切り取ります。 The bracket that fixes the magnet to the rotating shaft of the generator motor includes a pipe into which the rotating shaft is inserted, a left and right central hole disc that holds both ends of the magnet rotor, a power transmission plate that also serves as a partition to separate the magnetic poles, through bolts and nuts There are three types of power transmission plates for the metal fittings, T-type and T-type halves, hook-type, hook-type and T-type mixed. The use of a fan-shaped magnet with a width has the advantage of a strong rotational force, and the hook type uses a fan-shaped magnet with a size smaller than the coil width, and the number of power transmission plates is doubled. There is an advantage that the left and right disk portions of the space between the hooks are also cut out to allow air to pass through the left and right disks so that air can be directly cooled while rotating the slot of the fixed coil. The length of the T-type power transmission plate in the direction of the rotating shaft is the length of the stator yoke, and a 10mm high and 10mm long step is made on the right disk side on the rotating shaft side. The 10mm step is inserted into the right disk. For the reinforcement of the power transmission plate, a member with a 23 mm wide radius on the coil side of the power transmission plate is made about 15 mm longer than the length of the stator yoke, and the longer side becomes the coil side on the 10 mm step side of the power transmission plate. The power transmission plate is welded to the center so that the radius is divided in half, and the rounded portion is used as a magnet pop-out prevention presser for the left and right magnetic poles. And The length of the hook-shaped power transmission plate in the rotation axis direction is 30 mm longer than the position on the left side of the stator yoke, and a step of 10 mm in height and 10 mm in height is made from the fixed position of the right stator yoke to the rotation axis side. The left power transmission plate and the right power transmission plate are left and right in the direction seen from the rotational direction. The left power transmission plate has a 3 mm cut into which the left disk is inserted 30 mm from the left side of the left power transmission plate. The 10mm step, which is cut to half the height, is inserted into the right disk to reinforce the power transmission plate, and the left side magnet pops out with a 10mm width on the left side of the coil side of the 3mm cut end of the power transmission plate. The prevention presser is welded to the power transmission plate by extending it to the right by about 15 mm from the length of the stator yoke. The part of the hook type power transmission plate that protrudes toward the air passage side is bent to the passage side to prevent the magnet retainer from squeezing. The right power transmission plate is the length of the stator yoke, and from the fixed position of the right stator yoke to the rotating shaft side. A 10 mm long and 10 mm high step is made on the right side of the power transmission plate, and a 10 mm wide rounded right magnet pop-out prevention presser is made 15 mm longer on the 10 mm step side coil side to the power transmission plate. Weld, 15mm long part is turned 90 degrees to the rotating shaft side after rotor assembly, and then the part of the hook-shaped power transmission plate that protrudes to the air passage side is bent to the passage side to prevent the magnet presser from turning. The 30mm air introduction fan plate that protrudes to the left disk side of the left power transmission plate is fixed at an angle to the air introduction passage. The air introduction fan plate of the right power transmission plate is cut off from the right power transmission plate of the right disk. The T-type power transmission plate is fixed at an angle on the side of the air introduction passage, and the height of the power transmission plate is the length from the inner peripheral side of the fixed coil to the pipe covering the rotating shaft. A hole is formed in the disk in the center of the fan-shaped magnet at a position of 6mm, and the length of the 5mm long bolt is 15mm longer than the stator yoke. The left disk, magnet, and right disk are fixed with a stainless steel bolt or iron bolt. Positioning bolt through holes and bolts. Also, the two discs have a hole in the center where the pipe enters, and the right disc has a 3.5mm cut into which the 10mm step of the power transmission plate is inserted. 2 poles cut 10.5mm upward from the hole, 4 poles if 4 poles, 6 poles if 6 poles are divided into 6 left and right equally from the bolt hole, and a fixed coil on the disc 4 air cooling plates on the left and right Bolt holes are drilled in the same place as the T-type power transmission plate in the two disks of the key-type power transmission plate that are in contact, but the disk of the air introduction passage made by the left and right power transmission plates of the key-type power transmission plate The part where the notch is equally divided from the bolt hole, 2 places for 2 poles, 4 places for 4 poles, 6 places for 6 poles, the part where the left and right power transmission plates enter, from the rotating shaft to the fixed coil of the disk Cut the coil side from two disks from half of the length.

扇形磁石を回転軸に固定する金具の固定は、Ｔ型動力伝達板を配設、または、かぎ型動力伝達板を配設、または、Ｔ型と、かぎ型の動力伝達板を混合で配設する、などの３種類の磁石固定金具がありどの配設も少しずつ違うモータ性能になる、回転軸が軽い圧力で入るステータ ヨークより左右に２０ｍｍ長くした、薄い２ｍｍから３ｍｍのパイプを回転軸ロータ定位置のステータ ヨークから２０ｍｍ出た位置まで押し込んで、パイプの片側と回転軸とを全周溶接する、溶接してない側のパイプのステータ ヨークの左側位置と同位置に左側円盤をパイプと溶接します、その左側円盤とパイプに動力伝達板のめくれ防止が付いて無い方を溶接します、この円盤とパイプの溶接と動力伝達板とパイプの溶接でパイプが熱で収縮して回転軸に固定される、2磁極は2箇所に４磁極は４箇所に、６磁極は６箇所に円盤の６ｍｍ磁石穴を伝達板と伝達板の中心として等分した所に伝達板を溶接します、左側円盤と動力伝達板は片側全部を溶接、パイプと動力伝達板はタップ溶接とする、左側円盤のボルト穴にボルトを差し込んでボルトの頭を仮止め溶接します、かぎ型左右の動力伝達板も左側円盤には溶接で固定します、また、かぎ型とＴ型混合動力伝達板の6極の空気通路口は2箇所と3箇所と4箇所と数を増す配設もある、左側円盤と回転軸パイプに均等にＴ型、かぎ型、Ｔ型、かぎ型、Ｔ型、かぎ型、配設の空気通路３箇所と、また、Ｔ型、かぎ型、かぎ型、Ｔ型、かぎ型、かぎ型、配設の空気通路４箇所がある、また、Ｔ型動力伝達板を使用するロータの左右の円盤に、配設前に円盤中央に回転軸パイプ挿入穴と磁石中央穴を開け、右側円盤にだけＴ型動力伝達板補強の１０ｍｍ差込部が入る伝達板の数だけの切り込みを設ける、また、かぎ型動力伝達板を使用するロータの左右の円盤には扇形磁石中央穴を設けて、空気通路の所を切り取り、右側円盤だけかぎ型動力伝達板の補強の１０ｍｍ差込部が入る伝達板の数だけの切り込みを設ける、かぎ型とＴ型の混合伝達板も同様に穴と切り込みを設ける。   Fixing the metal fittings that fix the fan-shaped magnet to the rotating shaft is possible by arranging a T-type power transmission plate, or a hook-type power transmission plate, or a mixture of T-type and hook-type power transmission plates. There are three types of magnet fixing brackets, etc., and each arrangement has a slightly different motor performance. The rotating shaft enters the rotor shaft with light pressure. Push to the position of 20mm from the stator yoke at the fixed position, weld one side of the pipe and the rotating shaft all around, weld the left disk to the pipe at the same position as the left side of the stator yoke on the unwelded pipe The left disk and the pipe are welded to the pipe without the power transmission plate turning prevention. The welding of the disk and pipe and the power transmission plate and the pipe causes the pipe to shrink due to heat and turn to the rotating shaft. Fixed 2 magnetic poles, 2 magnetic poles, 4 magnetic poles in 4 locations, 6 magnetic poles in 6 locations, the transmission plate is welded to the transmission plate and the center of the transmission plate equally divided into 6mm magnet holes. The power transmission plate is welded on all sides, and the pipe and power transmission plate are tapped. The bolts are inserted into the bolt holes on the left disk and the bolt heads are temporarily welded. It is fixed by welding, and the 6-pole air passage opening of the hook type and T type mixed power transmission plate is also arranged in 2 places, 3 places and 4 places, the left disk and the rotating shaft pipe Equally T-shaped, hook-shaped, T-shaped, hook-shaped, T-shaped, hook-shaped, three air passages arranged, and T-shaped, hook-shaped, hook-shaped, T-shaped, hook-shaped, hook-shaped, There are four air passages in the arrangement, and on the left and right disks of the rotor using the T-type power transmission plate, in the center of the disk before installation A rotor that uses a key-type power transmission plate, with a shaft-shaft pipe insertion hole and a magnet center hole, and provided with notches as many as the number of transmission plates into which the 10-mm insertion portion of the T-type power transmission plate is inserted only in the right disk. The left and right discs are provided with fan-shaped magnet central holes, cut out the air passages, and the right disc is provided with notches as many as the number of transmission plates that can be inserted into the 10mm insertion portion of the key type power transmission plate. And T-shaped mixed transmission plate are also provided with holes and cuts.

扇形磁石取り付け金具が回転軸に付いたら、動力伝達板と動力伝達板の真ん中に差し込んである６ｍｍボルトを外周側がＮ極の扇形磁石の穴に通して同磁石を、たとえば、７枚差し仕込んだら、７枚目をナットで動力伝達板のめくれ防止の所までナットで締め付けて固定しステータ ヨークの長さの中で均等に並べる、これで回転軸１磁石極のＮ磁石極が出来ました、このような磁石の固定の仕方で回転軸上に、全部の扇形磁石がナットで締め付けて固定したら、動力伝達板から１５ｍｍ出ている、めくれ防止を回転軸方向に直角に曲げる、最後に右側円盤に回転軸を差し込んで、またボルトを穴に通して、また、動力伝達板が遠心力で飛び出し防止の１０ｍｍの段を差し込んで、最後にボルトにナットを締めて右側円盤を固定して、ナットとボルトを樹脂系のノリで固めてナットの回り止めをし、2磁極と４磁極と６磁極の扇形磁石を固定金具の中で均等に並べると回転軸に磁石リングが出来ます、２極と４極と6極のステータ ヨークの長さの枚数の磁石リングと７磁石リングと６磁石リングと５磁石リングと磁石枚数を減らすと、それぞれに違う回転範囲と入力電流値とがあり、用途により使い分けが出来る、また、ロータが大型の場合は2極のように反発する同極同士を2列並べて1磁石極としてロータを構成して、動力伝達板はＴ型を使用する、2極は4枚、4極は8枚、6極は12枚の動力伝達板とする。   When the fan-shaped magnet mounting bracket is attached to the rotating shaft, insert the 6 mm bolt inserted in the middle of the power transmission plate and the power transmission plate through the hole of the N-pole fan magnet and insert the same magnet, for example, 7 The 7th piece is tightened with a nut and fixed to the place where the power transmission plate is prevented from turning over, and is arranged evenly within the length of the stator yoke. When all the fan-shaped magnets are tightened and fixed on the rotating shaft with nuts in this way, the curling prevention is bent at a right angle to the rotating shaft direction. Insert the rotating shaft into the hole, pass the bolt through the hole, insert the 10mm step that prevents the power transmission plate from popping out by centrifugal force, and finally tighten the nut to the bolt to fix the right disk, The bolts are fixed with resin glue to prevent the nut from rotating, and the 2-pole, 4-pole, and 6-pole fan-shaped magnets are evenly arranged in the mounting bracket, and a magnet ring can be formed on the rotating shaft. When the number of magnet rings, 7 magnet rings, 6 magnet rings, 5 magnet rings and the number of magnets is reduced as the number of magnet rings, the number of poles and the number of stator yokes, the number of magnets is different. In addition, when the rotor is large, the rotor is configured as a single magnet pole by arranging two rows of repulsive identical poles like 2 poles, and the power transmission plate uses a T-type, 4 poles are 2 poles , 4 poles have 8 power transmission plates and 6 poles have 12 power transmission plates.

逆起電力と起電力の発電モータに配設のステータ ヨークの回転軸方向の長さに対しての扇形磁石の磁石リングと磁石リングの配設する間隔は2磁極と４磁極ロータと６磁極ロータとも同じで、配設する扇形磁石の厚みを磁石リングと磁石リングの間隔と決めて配設したロータを基本磁石リングとして、その配設から更に回転力を上げるには、１磁石リングずつ増やします、このように配設をした磁石リングの2極と４極と６極の逆起電力と起電力の発電モータの扇形磁石の厚みの間隔で配設した基本磁石リングロータは端子台での入力線の結線は、低速回転はスター結線、高速回転はデルタ結線します、低速と高速を繰り返す時は、スター結線とデルタ結線とを回転数、または、周波数、または、発電電圧を感知してスター結線とデルタ結線を自動で切り替えるようにする、また、磁石の厚みの間隔で配設するとは、ステータ ヨーク内側の回転軸方向の1個のコイルを構成しているスロットからスロットまでの回転軸方向の表面積の半分を扇形磁石で占める割合を基本磁石リングとする、基本から磁石のリング数を下げると発電と軽い回転負荷には使える、基本から磁石のリング数を上げると回転力と発電に使えるが長時間運転の周波数の範囲が狭い、また、２極発電モータと４極発電モータと６極発電モータの固定コイルの回転励磁コイル磁束は鉄芯ロータ用の定格コイル巻き数が基礎となる、磁力を強力にすると回転励磁コイル磁束を下げて、磁力を下げると回転励磁コイル磁束を上げる必要がある、磁石は磁束を調整出来ないので回転励磁コイルで磁束を調整する、たとえば、固定コイルの回転励磁磁束を作り出すエナメル絶縁皮膜電線の基礎巻き数から巻き数を減らす、または、エナメル絶縁皮膜電線２本巻き固定コイルは１本巻きエナメル絶縁皮膜電線で回転励磁磁束を作り出す、三相入力線を１本巻きエナメル絶縁皮膜電線で回転力が弱い場合は、三相入力線の１相、２相、３相、の１相を２本巻きに戻す、それでも弱い場合は３相を２本に戻す、絶縁皮膜電線３本巻き、４本巻きでも同じで始めに半分の磁束から発電モータの使用目的で１相ずつ元に戻す。   The stator ring arranged in the counter electromotive force and the electromotive force generating motor is arranged with respect to the length in the direction of the rotation axis of the yoke. In the same way, if the thickness of the fan-shaped magnet to be installed is determined as the gap between the magnet ring and the rotor is used as the basic magnet ring, increase the rotational force further by one magnet ring. The basic magnet ring rotor arranged at the interval of the thickness of the counter magnet of the 2-pole, 4-pole, and 6-pole counter electromotive force and the electromotive force of the generator motor is arranged at the terminal block. For wire connection, low speed rotation is star connection, and high speed rotation is delta connection.When low speed and high speed are repeated, the star connection and delta connection are detected by detecting the rotation speed, frequency, or generated voltage. Connection and delta connection Switching automatically and arranging at intervals of the magnet thickness means that half the surface area in the rotation axis direction from slot to slot constituting one coil in the rotation axis direction inside the stator yoke. The ratio of fan magnets is the basic magnet ring. If the number of magnet rings is reduced from the basic, it can be used for power generation and light rotational loads. The frequency range is narrow, and the rotational excitation coil magnetic flux of the fixed coils of 2-pole generator motors, 4-pole generator motors and 6-pole generator motors is based on the rated number of coil turns for the iron core rotor. Lowering the rotational excitation coil magnetic flux and lowering the magnetic force requires an increase in the rotational excitation coil magnetic flux. Since the magnet cannot adjust the magnetic flux, adjust the magnetic flux with the rotational excitation coil. Three-phase, which reduces the number of turns from the basic winding number of the enamel insulated film wire that generates the rotational excitation magnetic flux of the constant coil, or the double coil fixed winding coil of the enamel insulated film wire creates the rotational excitation magnetic flux with the single wound enamel insulated film wire If the rotational force is weak with a single-turn enameled insulated wire, return the 1-phase, 2-phase, and 3-phase of the 3-phase input wire to 2 windings. Returning to the book, the same is true for three or four insulation coated wires.

逆起電力と起電力の発電モータ、2磁極回転軸ロータと４磁極回転軸ロータの基本磁石リングと６磁石リングと７磁石リングの入力線コイルに、流れる回転電流値が２０アンペアを超えないインバータ出力の周波数回転範囲を調べました、電流値は発電モータの入力線のＵ、Ｖ、Ｗ、端子台で１本の導線に、ＡＣ測定のクランプメータを付けて連続で測定した、使用した2極発電モータ、４極発電モータのステータ ヨークの長さは１００ｍｍ、扇形磁石の厚みは１０ｍｍ、高さ３５ｍｍのネオジウム磁石です、また、６極発電モータの６磁極回転軸ロータの基本磁石リングと９磁石リングでステータ ヨークの長さは１６０ｍｍ、扇形磁石の厚みは１０ｍｍ、高さ３５ｍｍのネオジウム磁石です、また、ネオジウム磁石の扇形で厚みが６ｍｍで高さが３５ｍｍの基本磁石リングの回転周波数と入力線コイルの電流値も同じと成り、磁石が厚くても薄くても基本磁石リング配設なら同様な性能に成ります。   Inverter whose rotational current value does not exceed 20 amperes in the basic magnet ring, 6 magnet ring and 7 magnet ring input wire coil of back electromotive force and electromotive force generator motor, 2 magnetic pole rotating shaft rotor and 4 magnetic pole rotating shaft rotor The frequency rotation range of the output was examined. The current value was measured continuously with an AC measurement clamp meter attached to one lead wire at the U, V, W, terminal block of the generator motor. The stator yoke of the pole generator motor and the quadrupole generator motor is a neodymium magnet with a length of 100 mm, a fan magnet with a thickness of 10 mm, and a height of 35 mm. The magnet ring is a neodymium magnet with a stator yoke length of 160 mm, a fan magnet thickness of 10 mm and a height of 35 mm, and a neodymium magnet fan shape with a thickness of 6 mm. The current value of the input coil and the rotation frequency of the fundamental magnetic rings of Saga 35mm also become the same, will become the same performance if even basic magnetic rings arranged thin but thick magnet.

２磁極回転軸ロータが挿入される逆起電力と起電力の２極発電モータの、ネオジウム扇型磁石と回転励磁コイルの調整、２極発電モータの固定コイルのスロット数は、１２と２４と３６番のスロットが有るが１番から１２番スロットのところは、入力回転励磁１相と３相が左巻きコイルで２相が右巻きコイル、中性点回転励磁１相と３相が右巻きコイルで２相が左巻きコイル、入力回転励磁１相１番コイルの１番スロットから６番スロットに左巻きコイル配設、１番スロット末端導線に入力線を付ける、６番コイル末端導線を２番コイルの１２番スロットから７番スロットに右巻きコイル配設、７番スロット末端導線を１相中性点とする。入力回転励磁２相１番コイルの８番スロットから３番スロットに右巻きコイル配設、８番スロット末端導線に入力線を付ける、３番スロット末端導線を２番コイルの９番スロットから２番スロットに左巻きコイル配設、２番スロット末端導線を２相中性点とする。入力回転励磁３相１番コイルの５番スロットから１０番スロットに左巻きコイル配設、５番スロット末端導線に入力線を付ける、１０番スロット末端導線を２番コイルの４番スロットから１１番スロットに右巻きコイル配設、１１番スロット末端導線を３相中性点とする配線の、２極発電モータで扇型磁石のリング数を減らし力の弱いモータの場合は磁束調整が出来るが、基本リングに３リングまたは４リングと増したときに磁束調整が出来ないので、回転励磁コイルの磁束を調整する、発電モータは鉄芯ロータの回転励磁磁束巻き数が基礎になる為に、磁石ロータを発電モータに挿入すると回転励磁磁束が強すぎるために、始動回転の電流値が高くなる為に回転励磁磁束を下げる必要があり、固定コイルのエナメル絶縁皮膜電線の巻き数ではなく、巻き本数を減らします、たとえば、２本の絶縁皮膜電線でコイル定格巻き数の絶縁皮膜電線コイルの１本は回転励磁コイルに使用、１本は予備または、発電コイルとして使用すると負荷の軽い作業は出来るが、負荷の重い作業は１相だけ２本の絶縁皮膜電線を回転励磁コイルに戻す、それでも力が足りない場合は３相を２本の絶縁皮膜電線を回転励磁コイルに戻す、また軽作業の場合残った１本の予備または発電コイルは磁石ロータがコイルを通過後に発生する、逆起電力を回転励磁磁束の誘導作用により誘導起電力として予備または発電コイルに流れる、同時に回転励磁磁束の起電力も予備または発電コイルに流れる為、発電した起電力を負荷側に大電流を出力する場合は回転励磁の電流も流れる、また予備コイルとしてモータのコイル内に収める場合は漏電しないようにする。
Adjustment of the neodymium fan-shaped magnet and the rotary excitation coil of the counter electromotive force and electromotive force two-pole power generation motor into which the two-pole rotation shaft rotor is inserted are 12, 24, and 36, respectively. There are number slots, but in the 1st to 12th slots, input rotation excitation 1 phase and 3 phase are left-handed coils, 2 phases are right-handed coils, and neutral point rotation excitation 1-phase and 3 phases are right-handed coils. 2 phase left-handed coil, input rotation excitation 1-phase 1st coil 1st to 6th slot left-handed coil arrangement, 1st slot end conductor is connected to input wire, 6th coil end conductor is 12th coil A right-handed coil is arranged from the slot No. 7 to the slot No. 7, and the terminal lead of the slot No. 7 is set as a one-phase neutral point. Right-handed coil is provided from slot 8 to slot 3 of the input rotation excitation 2-phase 1 coil, and the input wire is attached to the end conductor of slot 8 and the end conductor of slot 3 is connected to slot 2 from coil 9 to slot 2. The left-handed coil is disposed in the slot, and the second slot terminal conductor is set as a two-phase neutral point. Left-handed coil is placed from slot 5 to slot 10 of the input rotation excitation 3-phase 1 coil, and the input wire is attached to the end conductor of slot 5, and the end conductor of slot 10 is inserted from slot 4 to slot 11 of coil 2. In the case of a 2-pole generator motor with a right-handed coil arrangement and wiring with the 11-slot end lead wire as the neutral phase of the three-phase, the number of fan-shaped magnet rings is reduced and the power is weak, the magnetic flux can be adjusted. Since the magnetic flux cannot be adjusted when the number of rings is increased to 3 or 4 rings, the generator motor that adjusts the magnetic flux of the rotating excitation coil is based on the number of rotation exciting magnetic flux turns of the iron core rotor. Since the rotational excitation magnetic flux is too strong when inserted into the generator motor, it is necessary to lower the rotational excitation magnetic flux in order to increase the starting rotation current value. Reduce the number of windings, for example, one insulated coating wire coil with two insulated coating wires and rated coil winding number is used for rotating excitation coil, one is spare or when used as a power generation coil, the load is light Work is possible, but for heavy work, return two insulated coating wires to the rotating excitation coil for one phase. If power is still insufficient, return three phases to the rotating excitation coil for three phases. In the case of light work, the remaining spare or generating coil is generated after the magnet rotor passes through the coil, and the counter electromotive force flows to the standby or generating coil as an induced electromotive force by the induction action of the rotating excitation magnetic flux. Therefore, when a large current is output from the generated electromotive force to the load, rotational excitation current also flows. If kept within yl is not to leak.

４磁極ロータ、基本磁石リング全体図Overall view of 4-pole rotor and basic magnet ring ６磁極ロータ、磁石リング右側動力伝達板円盤差し込み部と磁石押さえナット図6-pole rotor, magnet ring right side power transmission plate disk insertion part and magnet retainer nut ４磁極ロータ、かぎ型、Ｔ型混合動力伝達板を配設したロータ図Rotor diagram with 4-pole rotor, hook type, and T type mixed power transmission plate ２磁極ロータと２極固定コイル、2相逆巻きコイル図2-pole rotor, 2-pole fixed coil, 2-phase reverse coil ２磁極ロータ、かぎ型伝達板と扇形磁石2枚2-pole rotor, hook-shaped transmission plate and 2 fan magnets ２磁極ロータ、かぎ型とＴ型伝達板扇形磁石4枚2-pole rotor, hook and T-shaped transmission plate, 4 fan-shaped magnets

扇形磁石の中央に６ｍｍのステンレスボルトを通す穴を開けたので、磁石の定位置と倒れ防止と全体の固定が手作業で楽になった、１番楽に成ったのは磁石を何枚も１磁極に配設する時に、扇形磁石の穴にボルトを通す時にボルトがステータ ヨークより１５ｍｍ長くしてあるので、先に配設した磁石の磁力影響を直接受けない所で磁石の穴にボルトを入れられる、また、全ネジボルトなら１枚ずつナットで配設定位置に固定し手作業が楽です、動力伝達板と動力伝達板の間に扇形磁石を挿入時に、３ｍｍアール段部の左右の角が割れるために左右の角を３Ｃの面取りをした。     A hole for passing a 6mm stainless steel bolt in the center of the fan-shaped magnet makes it easier to fix the magnet in place, to prevent it from falling down, and to fix it as a whole. When the bolt is passed through the fan-shaped magnet hole, the bolt is 15 mm longer than the stator yoke, so that the bolt can be put into the magnet hole where it is not directly affected by the magnetic force of the previously arranged magnet. Also, if all screw bolts are fixed to the set position with nuts one by one, manual work is easy. When inserting a fan-shaped magnet between the power transmission plate and the power transmission plate, the left and right corners of the 3 mm rounded step breaks. Chamfered the corner of 3C.

図１は、４磁極ロータの基本磁石リングを４極の発電モータのロータとすると、周波数回転範囲は３０Ｈｚから１１０Ｈｚまで、６磁石リングをロータとすると、周波数回転範囲は３０Ｈｚから８０Ｈｚまで、７磁石リングをロータとすると、周波数回転範囲は３０Ｈｚから７０Ｈｚまで、この範囲なら長時間の運転負荷にも発熱しない、スター結線とデルタ結線との自動切り替えは周波数で５０Ｈｚから６０Ｈｚの間で切り替える。   FIG. 1 shows that when the basic magnet ring of the 4-pole rotor is a rotor of a 4-pole generator motor, the frequency rotation range is 30 Hz to 110 Hz, and when the 6-magnet ring is the rotor, the frequency rotation range is 30 Hz to 80 Hz, 7 magnets. When the ring is a rotor, the frequency rotation range is from 30 Hz to 70 Hz. If this range is used, heat is not generated even for a long-time operation load, and automatic switching between star connection and delta connection is switched between 50 Hz and 60 Hz in terms of frequency.

図２は、６磁極ロータの基本磁石リングを６極の発電モータのロータとすると、周波数回転範囲は３０Ｈｚから１００Ｈｚまで、９磁石リングをロータとすると、周波数回転範囲は３０Ｈｚから８０Ｈｚまで、スター結線とデルタ結線との自動切り替えは周波数で６０Ｈｚから７０Ｈｚの間で切り替える。   FIG. 2 shows that when the basic magnet ring of a 6-pole rotor is a rotor of a 6-pole generator motor, the frequency rotation range is 30 Hz to 100 Hz, and when the 9-magnet ring is a rotor, the frequency rotation range is 30 Hz to 80 Hz. And delta connection are automatically switched between 60 Hz and 70 Hz in frequency.

スター結線で、低速回転だけで負荷が軽い場合の回転は、2磁極と４磁極ロータと６磁極ロータの基本磁石リングから１から２磁石リングを取り外しても良い、また、基本磁石リング配設のロータをデルタ結線で高速回転だけとする場合は、 初めからデルタ結線で回転させる、また、入力線コイルの回転電流値が低い高速回転インバータ出力周波数は４磁極基本磁石リングで９０Ｈｚ出力の１．４０アンペアで回転する、６磁極基本磁石リングで８５Ｈｚ出力の１．７０アンペアで回転する、また、スター結線で回転力が弱い場合は、出力線もスター結線して、入力線のＵＶＷと出力線のＵＶＷをＵはＵに，ＶはＶに、ＷはＷに結線しますと回転力が上がります。   In the case of a star connection, if the load is light with only low speed rotation, the 1 to 2 magnet rings may be removed from the basic magnet rings of the 2-pole, 4-pole rotor, and 6-pole rotor. When the rotor is to be rotated at high speed only by delta connection, the rotor is rotated by delta connection from the beginning, and the rotation frequency of the input coil is low. Rotate at ampere, rotate at 1.70 ampere with 85Hz output with 6-pole basic magnet ring, and if the rotational force is weak with star connection, also connect the output line with star connection, UVW of input line and output line When UVW is connected to U, U to V, W to W, and W to W, the rotational force increases.

発電する動力モータとして、また、電気自動車。   As a power motor to generate electricity, it is also an electric vehicle.

１ 回転軸
２ パイプ
３ コイル冷却板
４ パイプと全周溶接止め左側円盤
５ 動力伝達板と扇形磁石の引っかかり部
６ 右側円盤とロータ全体固定通しボルト
７ ４磁極の基本磁石リングと磁石の厚み
８ めくれ防止曲げ部
９ 締め付けナットと樹脂系ノリで回り止め部
１０ 動力伝達板飛び出し防止円盤差込部
１１ 右側円盤
１２ パイプ全周溶接部
１３ 磁石の高さ
１４ 扇形磁石３ｍｍ段アール先端、２Ｃ面取り部
１５ かぎ型右側動力伝達板
１６ かぎ型左側動力伝達板と空気導入ファン板
１７ 空気通路と左右かぎ型動力伝達板の左側円盤と右側円盤の切り取り部
１８ かぎ型動力伝達板左右円盤差込み補強部
１９ Ｔ型動力伝達板
２０ １相入力線
２１ ２相入力線
２２ ３相入力線
２３ １相中性点
２４ ２相中性点
２５ ３相中性点 DESCRIPTION OF SYMBOLS 1 Rotating shaft 2 Pipe 3 Coil cooling plate 4 Pipe and whole circumference welding stop left disk 5 Power transmission plate and fan-shaped magnet catch part 6 Right disk and whole rotor fixed through bolt 7 Thickness of 4 magnets basic magnet ring and magnet 8 Turn Prevention bending part 9 Anti-rotation part 10 with tightening nut and resin glue 10 Power transmission plate pop-out prevention disk insertion part 11 Right disk 12 Pipe all-around welding part 13 Magnet height 14 Fan-shaped magnet 3mm step round tip, 2C chamfering part 15 Key-type right power transmission plate 16 Key-type left power transmission plate and air introduction fan plate 17 Air passage and left-side disk and right-side disk cut-out portion 18 of left-right key-type power transmission plate Key-type power transmission plate left-right disc insertion reinforcement 19 T Type power transmission plate 20 1-phase input line 21 2-phase input line 22 3-phase input line 23 1-phase neutral point 24 2-phase neutral point 25 3-phase neutral point

Claims (2)

４極発電機ロータに配設するネオジウム中央穴あき扇形磁石の取り付け金具は、回転軸パイプに通しボルト穴4個付き左側円盤を定位置に通して回転軸パイプと溶接固定されており、ロータ磁石極を分ける捲れ防止と補強差込付きＴ型動力伝達板４枚を左側円盤と回転軸パイプの4分割した定位置に溶接されてＴ型動力伝達板を固定されており、Ｔ型動力伝達板の長さは回転軸方向のステータ ヨークの長さと同じ長さとされており、回転方向左右のＴ型動力伝達板にネオジウム中央穴あき扇形磁石が挟まれており、4本の通しボルトがそれぞれ左側円盤のボルト穴及びネオジウム中央穴あき扇形磁石の穴に通されており、ネオジウム中央穴あき扇形磁石は、ナットで定位置に留められており、ナットから出ているボルトには、通しボルト穴4個とＴ型動力伝達板補強差込が入る4個の切り込みが有る右側円盤が通されており、右側円盤は別のナットで締められており、ロータ全体を固定した４極ロータの磁石極は回転方向にＮ、Ｓ、Ｎ、Ｓ、の配設で、磁石極は回転軸パイプ上の５ｍｍから１０ｍｍ径方向に浮いて回転軸パイプに平行に配設した構造となっており、ネオジウム中央穴あき扇形磁石は回転方向に扇形、厚みが６ｍｍまたは１０ｍｍで扇形のネオジウム扇形磁石の左右のロータ外周側には３ｍｍ深さで最小長１０ｍｍから最大長１５ｍｍの長さのＴ型動力伝達板磁石押さえ部が入るアールの付いた段が作られており、左右の段のＴ型動力伝達板の磁石押さえＴ型角部とネオジウム中央穴あき扇形磁石が接触する先端部を３Ｃの面取りがされており、ネオジウム中央穴あき扇形磁石の中央穴は６ｍｍでネオジウム中央穴あき扇形磁石の高さはステータ ヨークに接触しない最長接近部から回転軸パイプの５ｍｍまたは１０ｍｍ上部までの長さを高さとして、ネオジウム中央穴あき扇形磁石の磁極は固定コイル側と回転軸側に磁極を持たせた磁石で、回転方向の長さはステータ ヨーク内円周を４等分してＴ型動力伝達板の板厚分を引いた長さとされており、ロータ磁石極に配設するネオジウム中央穴あき扇形磁石の厚みが６ｍｍまたは１０ｍｍでネオジウム中央穴あき扇形磁石の１枚１枚が隣り合った磁石極同士が互いに磁束を出し、磁束で引き合いながら４枚のネオジウム中央穴あき扇形磁石でリング状を成す事を１磁石リングとし、各ボルトに磁石の厚みと同じ幅の間隔をあけて複数の磁石が配設されることで、ロータの1磁極が形成されており、配設した磁石の厚みを間隔として磁石を配設するとステータ ヨークの表面積の半分を、ネオジウム中央穴あき扇形磁石の表面積が覆う部分と成る４極発電機用ロータ。   The mounting bracket for the neodymium center hole fan-shaped magnet that is installed in the quadrupole generator rotor is welded and fixed to the rotating shaft pipe by passing the left disk with four bolt holes through the rotating shaft pipe to a fixed position. T-type power transmission plate is fixed by welding four T-type power transmission plates with prevention of twisting and reinforcing insertion to separate poles into a fixed position divided by 4 on the left disk and rotating shaft pipe. Is the same as the length of the stator yoke in the direction of the rotation axis. A fan-shaped magnet with a neodymium center hole is sandwiched between the T-type power transmission plates on the left and right in the rotation direction, and the four through bolts are on the left side. It is passed through the disk bolt hole and the hole of the neodymium center hole fan magnet, and the neodymium center hole fan magnet is held in place with a nut. And The right disk with four cuts is inserted, and the right disk is tightened with another nut, and the magnet pole of the 4-pole rotor that fixes the entire rotor is in the direction of rotation. With the arrangement of N, S, N, and S, the magnet pole floats in the radial direction from 5 mm to 10 mm on the rotating shaft pipe and is arranged in parallel to the rotating shaft pipe, and a neodymium central hole fan-shaped magnet Is a T-type power transmission plate magnet pressing part with a depth of 3 mm and a minimum length of 10 mm to a maximum length of 15 mm on the outer peripheral side of the left and right rotors of a fan-shaped neodymium fan-shaped magnet having a sector shape in the rotation direction and a thickness of 6 mm or 10 mm. A rounded step is made, and the tip of the T-shaped power transmission plate on the left and right sides of the T-shaped power transmission plate and the tip where the neodymium central perforated fan magnet contacts is chamfered with 3C. Perforated fan shape The center hole of the stone is 6mm, and the height of the fan magnet with a neodymium center hole is the length from the longest approaching part that does not contact the stator yoke to the 5mm or 10mm upper part of the rotary shaft pipe. The magnetic pole is a magnet having magnetic poles on the fixed coil side and the rotating shaft side, and the length in the rotational direction is the length obtained by dividing the circumference of the stator yoke into four equal parts and subtracting the thickness of the T-type power transmission plate. The magnet poles of the neodymium center holed fan-shaped magnets arranged on the rotor magnet poles are 6mm or 10mm and each one of the neodymium center holed fan-shaped magnets adjoin each other to generate magnetic fluxes and attract each other by magnetic flux On the other hand, forming a ring with four neodymium center hole fan magnets is a single magnet ring, and multiple bolts are arranged on each bolt with the same width as the magnet thickness. For quadrupole generators, one magnetic pole is formed, and when the magnets are arranged at intervals of the thickness of the arranged magnets, half of the surface area of the stator yoke is covered with the surface area of the neodymium center hole fan magnet. Rotor. ６極発電機ロータに配設するネオジウム中央穴あき扇形磁石の取り付け金具は、回転軸パイプに通しボルト穴６個付き左側円盤を定位置に通して回転軸パイプと溶接固定されており、ロータ磁石極を分ける捲れ防止と補強差込付きＴ型動力伝達板６枚を左側円盤と回転軸パイプの６分割した定位置に溶接されてＴ型動力伝達板を固定されており、Ｔ型動力伝達板の長さは回転軸方向のステータ ヨークの長さと同じ長さとされており、回転方向左右のＴ型動力伝達板にネオジウム中央穴あき扇形磁石が挟まれており、６本の通しボルトがそれぞれ左側円盤のボルト穴及びネオジウム中央穴あき扇形磁石の穴に通されており、ネオジウム中央穴あき扇形磁石は、ナットで定位置に留められており、ナットから出ているボルトには、通しボルト穴６個とＴ型動力伝達板補強差込が入る６個の切り込みが有る右側円盤が通されており、右側円盤は別のナットで締められており、ロータ全体を固定した６極ロータの磁石極は回転方向にＮ、Ｓ、Ｎ、Ｓ、Ｎ、Ｓ、の配設で、磁石極は回転軸パイプ上の５ｍｍから１０ｍｍ径方向に浮いて回転軸パイプに平行に配設した構造となっており、ネオジウム中央穴あき扇形磁石は回転方向に扇形、厚みが６ｍｍまたは１０ｍｍで扇形のネオジウム扇形磁石の左右のロータ外周側には３ｍｍの深さで最小長１０ｍｍから最大長１５ｍｍの長さのＴ型動力伝達板磁石押さえ部が入るアールの付いた段が作られており、左右の段のＴ型動力伝達板の磁石押さえＴ型角部とネオジウム中央穴あき扇形磁石が接触する先端部を３Ｃの面取りがされており、ネオジウム中央穴あき扇形磁石の高さはステータ ヨークに接触しない最長接近部から回転軸パイプの５ｍｍまたは１０ｍｍ上部までの長さを高さとして、ネオジウム中央穴あき扇形磁石の磁極は固定コイル側と回転軸側に磁極を持たせた磁石で、回転方向の長さはステータ ヨーク内円周を６等分されたＴ型動力伝達板の板厚分を引いた長さとされており、ロータ磁石極に配設するネオジウム中央穴あき扇形磁石の厚みが６ｍｍまたは１０ｍｍの１枚１枚が隣り合った磁石極同士が互いに磁束を出し、磁束で引き合いながら６枚のネオジウム中央穴あき扇形磁石でリング状を成す事を１磁石リングとし、各ボルトに磁石の厚みと同じ幅の間隔をあけて複数の磁石が配設されることで、ロータの１磁極が形成されており、配設した磁石の厚みを間隔として磁石を配設するとステータ ヨークの表面積の半分を、ネオジウム中央穴あき扇形磁石の表面積が覆う部分と成る６極発電機用ロータ。   The mounting bracket for the neodymium center hole fan-shaped magnet that is installed in the 6-pole generator rotor is passed through the rotating shaft pipe, passed through the left disk with six bolt holes, and fixed to the rotating shaft pipe by welding. T-type power transmission plate is fixed by welding 6 pieces of T-type power transmission plate with squeezing prevention and reinforcement insertion to separate poles into fixed position divided into 6 parts of left disk and rotary shaft pipe. Is the same as the length of the stator yoke in the direction of the rotation axis, and a fan-shaped magnet with a neodymium center hole is sandwiched between the T-type power transmission plates on the left and right in the direction of rotation. It is passed through the disk bolt hole and the hole of the neodymium center hole fan magnet, and the neodymium center hole fan magnet is held in place with a nut, and the bolt coming out of the nut has a through bolt hole. The right disk with 6 notches for inserting the T-type power transmission plate reinforcement plug is inserted, the right disk is tightened with another nut, and the magnet pole of the 6-pole rotor fixing the entire rotor is With the arrangement of N, S, N, S, N, and S in the rotation direction, the magnet poles float in the radial direction from 5 mm to 10 mm on the rotation axis pipe and are arranged parallel to the rotation axis pipe. The neodymium central hole-shaped fan-shaped magnet is a T-shaped fan with a thickness of 6 mm or 10 mm and a fan-shaped neodymium fan magnet with a depth of 3 mm and a minimum length of 10 mm to a maximum length of 15 mm. There is a rounded step where the power transmission plate magnet holding part enters, and the tip of the left and right T type power transmission plate where the T-shaped corners of the T-type power transmission plate and the neodymium central perforated fan-shaped magnet are in contact with 3C Chamfered, Neojiu The height of the fan with a central hole in the center is the length from the longest approaching part that does not contact the stator yoke to the 5mm or 10mm upper part of the rotating shaft pipe. This is a magnet with a magnetic pole on the shaft side. The length in the rotation direction is the length obtained by subtracting the thickness of the T-type power transmission plate that is divided into six equal parts around the inner circumference of the stator yoke. The magnet poles of the adjacent neodymium center holed fan magnets with a thickness of 6 mm or 10 mm generate magnetic fluxes from each other, attracting each other with the magnetic flux, and forming a ring shape with the six neodymium central holey sector magnets. One magnet ring is formed, and a plurality of magnets are arranged on each bolt with an interval of the same width as the thickness of the magnet, so that one magnetic pole of the rotor is formed. Interval A rotor for a 6-pole generator in which half of the surface area of the stator yoke is covered with the surface area of the neodymium central hole fan magnet when the magnet is disposed.