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JP2011083139A - Rotary electric machine - Google Patents

Rotary electric machine Download PDF

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Publication number
JP2011083139A
JP2011083139A JP2009234185A JP2009234185A JP2011083139A JP 2011083139 A JP2011083139 A JP 2011083139A JP 2009234185 A JP2009234185 A JP 2009234185A JP 2009234185 A JP2009234185 A JP 2009234185A JP 2011083139 A JP2011083139 A JP 2011083139A
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Japan
Prior art keywords
rotor shaft
rotor
stator
rotor core
core
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Granted
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JP2009234185A
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Japanese (ja)
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JP5502421B2 (en
Inventor
Yusuke Matsuoka
佑将 松岡
Wataru Ito
伊藤  渉
Takanori Kisanuki
高徳 木佐貫
Takashi Endo
貴 遠藤
Yosuke Otsubo
洋輔 大坪
Masanori Ohashi
正典 大橋
Hironori Kato
裕典 加藤
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Toshiba Corp
Toshiba Industrial Products and Systems Corp
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Toshiba Corp
Toshiba Industrial Products Manufacturing Corp
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Priority to JP2009234185A priority Critical patent/JP5502421B2/en
Publication of JP2011083139A publication Critical patent/JP2011083139A/en
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Publication of JP5502421B2 publication Critical patent/JP5502421B2/en
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    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K1/00Details of the magnetic circuit
    • H02K1/06Details of the magnetic circuit characterised by the shape, form or construction
    • H02K1/22Rotating parts of the magnetic circuit
    • H02K1/32Rotating parts of the magnetic circuit with channels or ducts for flow of cooling medium
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K9/00Arrangements for cooling or ventilating
    • H02K9/19Arrangements for cooling or ventilating for machines with closed casing and closed-circuit cooling using a liquid cooling medium, e.g. oil

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Motor Or Generator Frames (AREA)
  • Motor Or Generator Cooling System (AREA)

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rotary electric machine capable of effectively cooling both a permanent magnet installed to a rotor core and a stator winding wound on a stator core. <P>SOLUTION: The rotary electric machine includes an injection hole 9c for the rotor core being mounted on a rotor shaft 9 for the rotary electric machine and injecting a coolant supplied into the rotor shaft 9 from the end of the anti-load side of the rotor shaft 9 to the inner surface of the rotor core 5 by a rotary centrifugal force. The rotary electric machine further includes guide ways 12a and 12b being mounted on the rotor shaft 9 and the outer surfaces of end plates 7 and 8, guiding the coolant supplied into the rotor shaft 9 to the outer peripheral sides of the end plate 7 and 8 by the rotary centrifugal force and scattering the coolant towards the end 15a of the stator winding 15. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

本発明は、永久磁石形の回転子を備えた回転電機に関する。   The present invention relates to a rotating electrical machine including a permanent magnet type rotor.

永久磁石形の回転子を備えた回転電機は、固定子とその界磁空間に配置された回転子とから構成され、回転子は、中空状の回転子軸と、外周に永久磁石が配置された回転子鉄心とから構成され、固定子は、固定子鉄心と、該固定子鉄心に巻装された固定子巻線とから構成されている。   A rotating electrical machine having a permanent magnet type rotor is composed of a stator and a rotor disposed in a field space thereof, and the rotor has a hollow rotor shaft and a permanent magnet disposed on the outer periphery. The stator is composed of a stator core and a stator winding wound around the stator core.

油(冷却液体)が循環する冷却回路は、回転子鉄心に形成されて永久磁石の径方向内側を軸方向に貫通する軸方向油路と、該油路に油を供給する供給手段とから構成され、該供給手段から回転子軸内に供給される油は、遠心力で回転子軸内に形成された油路から回転子鉄心に形成された軸方向油路に供給されて回転子鉄心を冷却することにより永久磁石を冷却し、その後、固定子巻線の端部(コイルエンド)に供給されてその端部を冷却することにより固定子巻線全体を冷却するとしている(例えば、特許文献1参照)。   A cooling circuit through which oil (cooling liquid) circulates is composed of an axial oil passage formed in the rotor core and penetrating inward in the radial direction of the permanent magnet in the axial direction, and supply means for supplying oil to the oil passage. The oil supplied from the supply means into the rotor shaft is supplied by centrifugal force from the oil passage formed in the rotor shaft to the axial oil passage formed in the rotor core, and the rotor core is The permanent magnet is cooled by cooling, and then supplied to the end (coil end) of the stator winding to cool the entire stator winding by cooling the end (for example, Patent Documents). 1).

特開平9−182374号公報Japanese Patent Laid-Open No. 9-182374

しかしながら、上記構成では、冷却用の油は、回転子鉄心に形成された軸方向油路を流れた後に、コイルエンドに供給される。このため、軸方向油路から噴出された油がコイルエンドに充分に供給されるか否か不明であり、また、供給されたとしても、軸方向油路によって温められた油がコイルエンドに供給されるため、コイルエンド、延いては固定子巻線全体を充分に冷却することができなかった。   However, in the above configuration, the cooling oil is supplied to the coil end after flowing through the axial oil passage formed in the rotor core. For this reason, it is unclear whether the oil ejected from the axial oil passage is sufficiently supplied to the coil end, and even if it is supplied, the oil warmed by the axial oil passage is supplied to the coil end. As a result, the coil end and thus the entire stator winding cannot be sufficiently cooled.

本発明は、上記問題を解消するため、回転子鉄心に配設された永久磁石と固定子鉄心に巻装された固定子巻線との両方を効果的に冷却可能な回転電機を提供することを目的とする。   In order to solve the above problems, the present invention provides a rotating electrical machine capable of effectively cooling both a permanent magnet disposed on a rotor core and a stator winding wound around the stator core. With the goal.

上記目的を達成するために本発明の回転電機は、機枠と、この機枠の内周部に固定され、固定子巻線を有する固定子と、この固定子の界磁空間に配設された永久磁石形の回転子とを具備してなり、前記回転子は、電磁鋼板を積層してなる回転子鉄心と、この前記回転子鉄心の軸方向の両端面に配置された端板と、これらの端板及び回転子鉄心の中央部に挿通固定され、両端部が軸受を介して前記機枠に支持された中空状の回転子軸と、この回転子軸に設けられ、該回転子軸内にその反負荷側の端部から供給された冷却液体を回転遠心力により前記回転子鉄心内面に噴射させる回転子鉄心用噴射孔部と、前記回転子軸と前記端板の外面とに設けられ、前記回転子軸内に供給された冷却液体を回転遠心力により前記端板の外周側に案内して前記固定子巻線の端部に向け飛散させる案内路と、を備えて構成されていることを特徴とする(請求項1の発明)。   In order to achieve the above object, a rotating electrical machine of the present invention is provided in a machine frame, a stator fixed to the inner periphery of the machine frame, having a stator winding, and a field space of the stator. A permanent magnet-shaped rotor, and the rotor includes a rotor core formed by laminating electromagnetic steel sheets, and end plates disposed on both end faces in the axial direction of the rotor core; A hollow rotor shaft that is inserted into and fixed to the center portion of the end plate and the rotor core, and both ends are supported by the machine frame via bearings, and the rotor shaft is provided on the rotor shaft. Provided in the rotor core injection hole for injecting the cooling liquid supplied from the opposite end of the load into the inner surface of the rotor core by rotational centrifugal force, the rotor shaft and the outer surface of the end plate. The cooling liquid supplied into the rotor shaft is guided to the outer peripheral side of the end plate by a rotational centrifugal force, and the fixed liquid is guided. Characterized in that it is configured with a guide path for scattering toward an end portion of the slave windings (invention of claim 1).

上記手段によれば、回転子軸に形成された回転子鉄心用噴射孔部から回転軸の回転遠心力により回転子鉄心に噴射される冷却液体が永久磁石を冷却し、回転子鉄心の軸方向の両端面に配置された端板の外周側を案内された冷却液体が固定子巻線の端部を冷却するため、永久磁石と固定子巻線との両方を効率良く冷却することができる。   According to the above means, the cooling liquid sprayed to the rotor core by the rotational centrifugal force of the rotor shaft from the rotor core injection hole formed in the rotor shaft cools the permanent magnet, and the axial direction of the rotor core Since the cooling liquid guided on the outer peripheral side of the end plates disposed on both end faces cools the end of the stator winding, both the permanent magnet and the stator winding can be efficiently cooled.

本発明の第1実施例を示す回転電機の縦断側面図1 is a longitudinal side view of a rotary electric machine showing a first embodiment of the present invention. 端板の拡大正面図Enlarged front view of end plate 図1に示す回転電機の右端部上半部の拡大図Enlarged view of the upper half of the right end of the rotating electrical machine shown in FIG. 本発明の第2実施例を示す図1相当図FIG. 1 equivalent view showing a second embodiment of the present invention. 本発明の第3実施例を示す端板の縦断側面図Longitudinal side view of an end plate showing a third embodiment of the present invention

(第1の実施形態)
以下、本発明の第1実施例について、図1乃至図3を参照しながら説明する。
図1に示すように、本実施例の回転電機は、その外郭を形成する有底円筒状の機枠1と、この機枠1の一部をなすべくその開口部1aを閉塞する蓋板2と、機枠1の内周部に圧入固定されている固定子3と、固定子3の内周部にあって界磁空間に回転自在に配置された永久磁石形の回転子4とを備える。
(First embodiment)
A first embodiment of the present invention will be described below with reference to FIGS.
As shown in FIG. 1, the rotating electrical machine of the present embodiment includes a bottomed cylindrical machine frame 1 that forms the outline of the rotating electric machine, and a lid plate 2 that closes the opening 1 a to form a part of the machine frame 1. And a stator 3 that is press-fitted and fixed to the inner peripheral portion of the machine frame 1, and a permanent magnet-shaped rotor 4 that is disposed in the inner peripheral portion of the stator 3 and is rotatably disposed in the field space. .

回転子4は、電磁鋼板(例えば、珪素鋼板)をプレス機により打抜き形成した円環状の多数枚の鉄心抜板を積層してなる回転子鉄心5を有する。回転子鉄心5の外周部には、複数個の永久磁石(磁極)6(図1中1個のみ図示)が等角度を存して埋設されている。そして、回転子鉄心5の軸方向の両端面には、図2に示す円環状の端板7、8が配置されている。回転子軸9は中空状をなすもので、その一方の端部たる反負荷側の端部(図1中左端部)の外周には、鍔部10が一体に形成されている。   The rotor 4 has a rotor core 5 formed by laminating a large number of annular core punched plates formed by punching and forming electromagnetic steel plates (for example, silicon steel plates) with a press. A plurality of permanent magnets (magnetic poles) 6 (only one is shown in FIG. 1) are embedded in the outer peripheral portion of the rotor core 5 at an equal angle. And the annular end plates 7 and 8 shown in FIG. 2 are arrange | positioned at the both end surfaces of the axial direction of the rotor core 5. As shown in FIG. The rotor shaft 9 has a hollow shape, and a flange portion 10 is integrally formed on the outer periphery of the opposite end portion (left end portion in FIG. 1) which is one end portion of the rotor shaft 9.

ここで、回転子軸9に回転子鉄心5、端板7及び8を組み込み固定する手順について述べる。まず、回転子軸9に一方の端板7をその他方の端部(図1中右端部)側から嵌め込んで鍔部10に当接するまで移動させる。次に、回転子軸9に回転子鉄心5を嵌め込んでその左端面が端板7に当接するまで移動させる。そして、回転子軸9の右端部に他方の端板8を嵌め込んだ後、回転子軸9に締結部材、例えばナット11を螺合させて締め付け、以て、回転子4の組立を完了する。   Here, a procedure for incorporating and fixing the rotor core 5 and the end plates 7 and 8 to the rotor shaft 9 will be described. First, one end plate 7 is fitted into the rotor shaft 9 from the other end (right end in FIG. 1) side and moved until it comes into contact with the flange 10. Next, the rotor core 5 is fitted into the rotor shaft 9 and moved until the left end surface thereof abuts against the end plate 7. Then, after the other end plate 8 is fitted into the right end portion of the rotor shaft 9, a fastening member, for example, a nut 11 is screwed onto the rotor shaft 9 and tightened to complete the assembly of the rotor 4. .

なお、図示はしないが、回転子軸9の外周面に等角度を存して2本のキーが軸方向に一体に延設形成されている。端板7、8及び回転子鉄心5の中央部には回転子軸9と略同じ大きさの貫通孔が形成され、この貫通孔の内周面に該キーに対応するキー溝が形成されており、該キーと該キー溝が係合されて、回転子軸9と端板7、8及び回転子鉄心5とが一体に回転する。   Although not shown, two keys are integrally formed extending in the axial direction at an equal angle on the outer peripheral surface of the rotor shaft 9. A through hole having substantially the same size as the rotor shaft 9 is formed in the center of the end plates 7 and 8 and the rotor core 5, and a key groove corresponding to the key is formed on the inner peripheral surface of the through hole. Thus, the key and the key groove are engaged, and the rotor shaft 9, the end plates 7 and 8, and the rotor core 5 rotate integrally.

回転子軸9は、機枠1の内部に位置する中空部と外部(負荷側)に位置する中実部とから構成されている。該中空部はその一端(図1中左側)が開口されており後述する冷却液体が、該開口から該中空部に注入される。なお、回転子軸9の中実部端部の外周面には、スプライン18が施されており、回転子軸9と図示しない負荷装置との連結(嵌合)に用いられる。   The rotor shaft 9 includes a hollow portion located inside the machine casing 1 and a solid portion located outside (load side). One end (left side in FIG. 1) of the hollow portion is opened, and a cooling liquid described later is injected into the hollow portion from the opening. In addition, the spline 18 is given to the outer peripheral surface of the solid part edge part of the rotor shaft 9, and it is used for connection (fitting) with the rotor shaft 9 and the load apparatus which is not shown in figure.

さて、端板7、8において回転子鉄心5の軸方向の左右両端面と接する面の反対側の面(外面)には、図2に示すように、内周7a、8aから外周7b、8b側に延びる断面矩形凹状の2つの溝7c、8cが等角度たる180度の角度を存して形成されている。該溝7c、8cの外周7b、8b側の開口は周方向に拡がり、断面矩形凹状の扇形開口部7d、8dが形成されている。   As shown in FIG. 2, the end plates 7 and 8 are arranged on the opposite surface (outer surface) of the end plates 7 and 8 that are in contact with the left and right end surfaces of the rotor core 5 in the axial direction. Two grooves 7c and 8c having a rectangular cross section extending to the side are formed at an equal angle of 180 degrees. The openings on the outer periphery 7b, 8b side of the grooves 7c, 8c are expanded in the circumferential direction, and fan-shaped openings 7d, 8d having a concave cross section are formed.

回転子軸9には、その中空部内を前記各2つの溝7c、8cに連通させる各2つの導入孔9a、9bが形成されている。従って、前記溝7c、8c及び導入孔9a、9bは、回転子軸9の中空部を端板7、8の外周側に連通させる案内路12a、12bを構成する。また、回転子軸9の外周部には、導入孔9aと導入孔9bとの略中間部に位置して回転子軸9の中空部内と連通する回転子鉄心用噴射孔部9cが等角度を存して2個形成されている。   The rotor shaft 9 is formed with two introduction holes 9a and 9b for communicating the inside of the hollow portion with the two grooves 7c and 8c. Accordingly, the grooves 7c and 8c and the introduction holes 9a and 9b constitute guide paths 12a and 12b that allow the hollow portion of the rotor shaft 9 to communicate with the outer peripheral side of the end plates 7 and 8. Further, at the outer periphery of the rotor shaft 9, there is an equiangular angle of the rotor core injection hole 9 c that is located approximately in the middle between the introduction hole 9 a and the introduction hole 9 b and communicates with the hollow portion of the rotor shaft 9. Two are formed.

固定子3は、円環状の多数枚の電磁鋼板を積層してなる固定子鉄心13と、この固定子鉄心13の図示しないスロット内にスロット絶縁紙14を介して収納して巻装された固定子巻線15とを備えている。なお、スロット絶縁紙14の径方向の開口部には、楔絶縁紙(図示せず)が配置されている。そして、回転子4は、固定子3の界磁空間に配置されて、その回転子軸9の両端が後述する軸受16a、16bに支承されるようになっており、以て、永久磁石形の回転電機が構成される。   The stator 3 is a stator core 13 formed by laminating a large number of annular magnetic steel sheets, and a stator 3 that is housed and wound in a slot (not shown) of the stator core 13 via a slot insulating paper 14. A secondary winding 15 is provided. Note that wedge insulating paper (not shown) is disposed in the radial opening of the slot insulating paper 14. The rotor 4 is disposed in the field space of the stator 3, and both ends of the rotor shaft 9 are supported by bearings 16a and 16b to be described later. A rotating electric machine is configured.

機枠1の閉塞端部の中央部には回転子軸9が貫通する貫通孔1bが形成されている。この貫通孔1bと回転子軸9との隙間には、後述する冷却液体が機枠1外に漏出するのを防止するためのシール材17が装着されている。貫通孔1bより機枠1の軸方向内側には軸受16aが装着されている。軸受16aと貫通孔1bとの間に位置する回転子軸9の外周部には、回転子軸9の中空部内と連通する軸受用噴射孔部9dが等角度を存して2個形成されている。   A through hole 1b through which the rotor shaft 9 passes is formed at the center of the closed end of the machine casing 1. A sealing material 17 for preventing cooling liquid, which will be described later, from leaking out of the machine casing 1 is mounted in the gap between the through hole 1b and the rotor shaft 9. A bearing 16a is mounted on the inner side in the axial direction of the machine casing 1 from the through hole 1b. Two bearing injection hole portions 9d communicating with the inside of the hollow portion of the rotor shaft 9 are formed at equal angles on the outer peripheral portion of the rotor shaft 9 positioned between the bearing 16a and the through hole 1b. Yes.

機枠1の開口部1aには、この開口部1aを閉塞する蓋板2が、複数本のボルト24(図1中2本のみ示す)により固定されている。蓋板2の中央部には、後述する冷却液体の投入用の投入口部19が形成されている。投入口部19は、蓋板2の裏側(機枠1側)にあって、その開口外周部に軸方向に突設した円環状の突設部20が一体に形成されている。蓋板2の裏側には、該突設部20より軸方向内側には軸受16bが装着され、軸受16bは、軸受16aとともに回転子軸9の中空部の両端部を回転自在に支持している。   A cover plate 2 that closes the opening 1a is fixed to the opening 1a of the machine frame 1 by a plurality of bolts 24 (only two are shown in FIG. 1). At the center of the cover plate 2, a charging port 19 for charging a cooling liquid, which will be described later, is formed. The insertion port portion 19 is on the back side (machine frame 1 side) of the cover plate 2, and an annular projecting portion 20 projecting in the axial direction is integrally formed on the outer peripheral portion of the opening. On the back side of the cover plate 2, a bearing 16b is mounted on the inner side in the axial direction from the projecting portion 20, and the bearing 16b rotatably supports both ends of the hollow portion of the rotor shaft 9 together with the bearing 16a. .

回転子軸9の中空部開口端部内周には、内径が他部より径大となる段部21が形成され、該段部21の内周部に投入口部19の突設部20が配置され、該段部21と該突設部20との間の間隙は、回転子軸9の中空部内部と連通し軸受16bに臨む空隙路22を形成する。蓋板2の下部には、機枠1の下部に溜まった冷却液体を外部に排出するための排出口部23が形成されている。   A step portion 21 having an inner diameter larger than that of the other portion is formed on the inner periphery of the hollow portion opening end of the rotor shaft 9, and the projecting portion 20 of the inlet port portion 19 is disposed on the inner periphery of the step portion 21. The gap between the stepped portion 21 and the projecting portion 20 forms a gap 22 that communicates with the inside of the hollow portion of the rotor shaft 9 and faces the bearing 16b. A discharge port portion 23 for discharging the cooling liquid accumulated in the lower portion of the machine casing 1 to the outside is formed at the lower portion of the cover plate 2.

次に、本実施例の作用につき説明する。
本実施例の永久磁石形の回転電機は、例えば、電気自動車(ハイブリッドカーを含む)の駆動電動機として用いられるもので、高速回転で運転されるようになっており、運転中は、機枠1内に貯留された冷却液体たる冷却油は、図示しないポンプにより排出口部23から汲み上げられ、図示しない例えばラジエータで冷却された後、投入口部19より回転子軸9の中空部内に供給される循環経路を流通するようになっている。
Next, the operation of this embodiment will be described.
The permanent magnet type rotating electrical machine of the present embodiment is used as, for example, a drive motor of an electric vehicle (including a hybrid car) and is operated at a high speed rotation. Cooling oil, which is a cooling liquid stored in the inside, is pumped up from the discharge port 23 by a pump (not shown), cooled by, for example, a radiator (not shown), and then supplied from the charging port 19 into the hollow portion of the rotor shaft 9. The circulation route is distributed.

固定子3の固定子巻線15に通電されて回転子4が回転すると、回転子軸9の中空部内に供給された冷却油が、回転遠心力により回転子鉄心用噴射孔部9cから回転子鉄心5の内面に噴射される。噴射された該冷却油は、回転遠心力により電磁鋼板が積層してなる回転子鉄心5の内部に生じる隙間に浸透し、回転子鉄心5の外周部に埋設されている永久磁石6を直接冷却し、また、回転子鉄心5を冷却することにより間接的に永久磁石6を冷却する。   When the stator winding 15 of the stator 3 is energized and the rotor 4 rotates, the cooling oil supplied into the hollow portion of the rotor shaft 9 is rotated from the rotor core injection hole 9c by the rotational centrifugal force. It is injected on the inner surface of the iron core 5. The injected cooling oil penetrates into a gap generated in the rotor core 5 formed by laminating electromagnetic steel plates by rotational centrifugal force, and directly cools the permanent magnet 6 embedded in the outer peripheral portion of the rotor core 5. In addition, the permanent magnet 6 is indirectly cooled by cooling the rotor core 5.

一方、固定子3の固定子巻線15に通電されて回転子4が回転すると、回転子軸9の中空部内に供給された冷却油は、回転遠心力により案内路12a及び12bに案内される。具体的には、冷却油は、導入孔9a及び9bから端板7及び8の溝7c及び8c内に導入され、更に、溝7c及び8cに案内され扇形開口部7d及び8dより固定子巻線15の端部(コイルエンド)15aに向けて噴射飛散される。即ち、該冷却油は、扇形開口部7d及び8dにより回転子4の回転周方向に拡がりながらコイルエンド15aへ向かって飛散される。このため、冷却油は、運転中は常に広範囲に飛散されるためコイルエンド15aを均一に冷却することが可能である。   On the other hand, when the stator winding 15 of the stator 3 is energized and the rotor 4 rotates, the cooling oil supplied into the hollow portion of the rotor shaft 9 is guided to the guide paths 12a and 12b by the rotational centrifugal force. . Specifically, the cooling oil is introduced into the grooves 7c and 8c of the end plates 7 and 8 from the introduction holes 9a and 9b, and is further guided to the grooves 7c and 8c from the fan-shaped openings 7d and 8d. The spray is scattered toward the end 15 (coil end) 15a. That is, the cooling oil is scattered toward the coil end 15a while spreading in the rotational circumferential direction of the rotor 4 through the fan-shaped openings 7d and 8d. For this reason, since the cooling oil is always scattered over a wide range during operation, the coil end 15a can be uniformly cooled.

図3に示すように、固定子鉄心13の図示しないスロットに挿入されたスロット絶縁紙14は、固定子鉄心13の軸方向右側端面より軸方向外方に寸法Aだけ突出している。回転子鉄心5の軸方向右側端面は、固定子鉄心13の軸方向右側端面より軸方向外方に寸法B(本実施例では2〜3ミリ)だけ突出している。回転子鉄心5の軸方向右側端面から端板8の溝8cの底部までの距離は寸法Cである。寸法Bと寸法Cとの和は、寸法Aより大きくなるように設定されている((B+C)>A)。   As shown in FIG. 3, the slot insulating paper 14 inserted in a slot (not shown) of the stator core 13 protrudes from the right end surface in the axial direction of the stator core 13 by a dimension A outward in the axial direction. The axial right end surface of the rotor core 5 protrudes outward in the axial direction by a dimension B (2 to 3 mm in this embodiment) from the axial right end surface of the stator core 13. The distance from the axially right end surface of the rotor core 5 to the bottom of the groove 8c of the end plate 8 is the dimension C. The sum of dimension B and dimension C is set to be larger than dimension A ((B + C)> A).

従って、スロット絶縁紙14の軸方向右側端部から端板8の溝8cの底部までの軸方向距離は寸法(B−A+C)となり正の値となる((B−A+C)>0)。このため、端板8の溝8cの底部は、軸方向のコイルエンド15aの存する範囲内に位置することとなり、案内路12bから噴射飛散された冷却油が、端板8の溝8cの底部から該寸法(B−A+C)を越えて軸方向内側に飛散されてスロット絶縁紙14に衝突するようなことはない。従って、衝突により絶縁紙14を摩耗、損傷させるというようなことはなく、スロット絶縁紙14の摩耗、損傷による固定子巻線15の絶縁を低下させることはない。   Accordingly, the axial distance from the right end of the slot insulating paper 14 in the axial direction to the bottom of the groove 8c of the end plate 8 is a dimension (B−A + C), which is a positive value ((B−A + C)> 0). For this reason, the bottom part of the groove 8c of the end plate 8 is positioned within the range where the axial coil end 15a exists, and the cooling oil sprayed and scattered from the guide path 12b starts from the bottom part of the groove 8c of the end plate 8. There is no possibility that it will be scattered inward in the axial direction beyond the dimension (B−A + C) and collide with the slot insulating paper 14. Therefore, the insulation paper 14 is not worn or damaged by the collision, and the insulation of the stator winding 15 due to wear or damage of the slot insulation paper 14 is not lowered.

なお、回転電機の左端部についても、図示はしないが、上述した回転電機の右端部と同様の寸法構成となっている。即ち、スロット絶縁紙14は、固定子鉄心13の軸方向左側端面より寸法Aだけ突出している。回転子鉄心5の軸方向左側端面は、固定子鉄心13の軸方向左側端面より寸法B(本実施例では約2〜3ミリ)だけ突出している。固定子鉄心13の軸方向左側端面から端板7の溝7cの底部までの距離は寸法Cである。寸法Bと寸法Cとの和は、寸法Aより大きくなるように設定されている((B+C)>A)。   Note that the left end portion of the rotating electrical machine has the same dimensional configuration as that of the right end portion of the rotating electrical machine described above, although not shown. That is, the slot insulating paper 14 protrudes from the left end face in the axial direction of the stator core 13 by a dimension A. The axial left end surface of the rotor core 5 protrudes from the axial left end surface of the stator core 13 by a dimension B (about 2 to 3 mm in this embodiment). The distance from the left end surface in the axial direction of the stator core 13 to the bottom of the groove 7c of the end plate 7 is the dimension C. The sum of dimension B and dimension C is set to be larger than dimension A ((B + C)> A).

従って、スロット絶縁紙14の軸方向左側端部から端板7の溝7cの底部までの距離は寸法(B−A+C)となり正の値となる((B−A+C)>0)。このため、端板7の溝7cの底部は、軸方向のコイルエンド15aの存する範囲内に位置することとなり、案内路12aから噴射飛散された冷却油が、端板7の溝7cの底部から該寸法(B−A+C)を越えて軸方向内側に飛散されスロット絶縁紙14に衝突してこれらを摩耗、損傷させるというようなことはなく、スロット絶縁紙14の摩耗、損傷による固定子巻線15の絶縁を低下させることはない。   Accordingly, the distance from the left end in the axial direction of the slot insulating paper 14 to the bottom of the groove 7c of the end plate 7 is a dimension (B−A + C), which is a positive value ((B−A + C)> 0). For this reason, the bottom part of the groove 7c of the end plate 7 is positioned within the range where the axial coil end 15a exists, and the cooling oil sprayed and scattered from the guide path 12a starts from the bottom part of the groove 7c of the end plate 7. There is no such thing as being scattered inward in the axial direction beyond the dimension (B−A + C) and colliding with the slot insulating paper 14 to wear or damage them. The insulation of 15 is not lowered.

また、固定子3の固定子巻線15に通電されて回転子4が回転すると、回転子軸9の中空部内に供給された冷却油が、回転遠心力により軸受用噴射孔部9dから軸受16aに噴射飛散される。このことにより、軸受16aに充分な潤滑油を与えることができ、軸受16aの摩耗、焼き付き等の損傷を防止することができる。   Further, when the stator winding 15 of the stator 3 is energized and the rotor 4 rotates, the cooling oil supplied into the hollow portion of the rotor shaft 9 is rotated from the bearing injection hole 9d by the rotational centrifugal force to the bearing 16a. The jets are scattered. Thus, sufficient lubricating oil can be given to the bearing 16a, and damage such as wear and seizure of the bearing 16a can be prevented.

尚、固定側の蓋板2の投入口部19を回転側の回転子軸9とは非連結状態にあるので、投入口部19から回転子軸9の中空部内に供給された冷却油は、両者の間の隙間から外方に流出して回転子軸9の中空部内に充分に供給されなくなる虞がある。しかしながら、本実施例では、投入口部19の突設部20と回転子軸9の段部21とで形成される空隙路22が、回転子軸9の回転にともなって空気流を生じてラビリンスシールを形成するようになり、従って、冷却油が不用意に外部に流出することはない。   Since the inlet 19 of the fixed lid 2 is not connected to the rotor shaft 9 on the rotation side, the cooling oil supplied from the inlet 19 into the hollow portion of the rotor shaft 9 is There is a possibility that the gas flows out from the gap between the two and is not sufficiently supplied into the hollow portion of the rotor shaft 9. However, in this embodiment, the air gap 22 formed by the projecting portion 20 of the charging port portion 19 and the step portion 21 of the rotor shaft 9 generates an air flow with the rotation of the rotor shaft 9, resulting in a labyrinth. A seal is formed, so that the cooling oil does not inadvertently flow out to the outside.

但し、回転子軸9の中空部内に冷却油が充満した場合には、前述したラビリンスシール効果はなくなり、冷却油は空隙路22を経て軸受16bに至り、これを冷却して外方に流出する。   However, when the cooling oil is filled in the hollow portion of the rotor shaft 9, the labyrinth sealing effect described above is lost, and the cooling oil reaches the bearing 16b through the gap path 22, and cools and flows outward. .

このような本実施例によれば、固定子3の固定子巻線15に通電されて回転子4が回転すると、回転子軸9の中空部内に供給された冷却油は、回転遠心力により回転子軸9の導入孔9a及び9bから案内路12a及び12bに案内されコイルエンド15aへ向かって飛散され、コイルエンド15a延いては固定子巻線15全体を冷却することができる。この場合、回転子鉄心用噴射孔部9cからも冷却油が噴射され、該冷却油は、回転子鉄心5内に生じた隙間に浸透して永久磁石6をも冷却する。従って、従来とは異なり、永久磁石6と固定子巻線15との両方を効率良く冷却することができる。   According to this embodiment, when the rotor 4 is rotated by energizing the stator winding 15 of the stator 3, the cooling oil supplied into the hollow portion of the rotor shaft 9 is rotated by the rotational centrifugal force. The guide shafts 12a and 12b are guided from the introduction holes 9a and 9b of the core shaft 9 and scattered toward the coil end 15a, and the coil end 15a and the entire stator winding 15 can be cooled. In this case, cooling oil is also injected from the rotor core injection hole 9 c, and the cooling oil penetrates into the gap formed in the rotor core 5 to cool the permanent magnet 6. Therefore, unlike the prior art, both the permanent magnet 6 and the stator winding 15 can be efficiently cooled.

上記実施例に対し、図4及び図5は、本発明の第2及び第3実施例を示すもので、上記第1実施例と実質的に同一部分には同一符号を付して説明を省略し、異なる点につき説明する。   4 and 5 show the second and third embodiments of the present invention with respect to the above embodiment, and the same reference numerals are given to substantially the same parts as those in the first embodiment, and the description is omitted. The differences will be explained.

(第2の実施形態)
以下、本発明の第2実施例について図4を参照しながら説明する。
本実施例は、機枠1に代わる機枠31は、下部に矩形容器状の油溜まり33を下方に延設形成した点において、上記第1実施例の構成と異なる。
(Second Embodiment)
Hereinafter, a second embodiment of the present invention will be described with reference to FIG.
The present embodiment differs from the first embodiment in that a machine frame 31 that replaces the machine frame 1 has a rectangular container-like oil reservoir 33 that extends downward.

図4に示すように、本実施例の回転電機は、その外郭を形成する有底円筒状の機枠31と、この機枠31の開口部31aを閉塞する蓋板32と、機枠31の内周部に圧入固定されている固定子3と、固定子3の内周部にあって界磁空間に回転自在に配設された永久磁石形の回転子4とを備える。   As shown in FIG. 4, the rotating electrical machine according to the present embodiment includes a bottomed cylindrical machine casing 31 that forms an outline of the rotating electric machine, a cover plate 32 that closes an opening 31 a of the machine casing 31, and the machine casing 31. A stator 3 that is press-fitted and fixed to the inner peripheral portion, and a permanent magnet-shaped rotor 4 that is disposed in the inner peripheral portion of the stator 3 and is rotatably disposed in the field space.

油溜まり33は、機枠31の下部であって固定子3の下側に配設されている。蓋板32は、その中央部に回転子軸9の中空部に連通する投入口部34が形成され、その下部には油溜まり33に溜まった冷却油を外部に排出するための排出口部35が形成されている。   The oil sump 33 is disposed below the machine casing 31 and below the stator 3. The lid plate 32 is formed with a charging port portion 34 communicating with the hollow portion of the rotor shaft 9 at the center thereof, and a discharge port portion 35 for discharging cooling oil accumulated in the oil reservoir 33 to the outside at the lower portion thereof. Is formed.

油溜まり33に貯留された所定量の冷却油は、図示しないポンプにより排出口部35から汲み上げられ、例えばラジエータで冷却された後、投入口部34より機枠1内に注入される。該冷却油は、その後、回転子軸9の中空部内に供給され、回転遠心力により回転子軸9から噴射された冷却油は再び油溜まり33に貯留される。   A predetermined amount of cooling oil stored in the oil reservoir 33 is pumped up from the discharge port 35 by a pump (not shown), and is cooled by, for example, a radiator, and then injected into the machine frame 1 from the input port 34. Thereafter, the cooling oil is supplied into the hollow portion of the rotor shaft 9, and the cooling oil injected from the rotor shaft 9 by the rotational centrifugal force is stored again in the oil reservoir 33.

このような本実施例によれば、上記した第1実施例と同様の効果を得ることができ、更に以下の効果を得ることができる。
機枠31の下部には、油溜まり33が形成されているので、回転子軸9から機枠31内に噴射された冷却油は、最終的には油溜まり33に流下貯留されるようになり、従って、循環経路に円滑に吸入されて流通するようになる。
According to such a present Example, the effect similar to 1st Example mentioned above can be acquired, and also the following effects can be acquired.
Since the oil reservoir 33 is formed in the lower part of the machine frame 31, the cooling oil injected into the machine frame 31 from the rotor shaft 9 finally flows down and is stored in the oil reservoir 33. Therefore, the air is smoothly drawn into the circulation path and circulates.

(第3の実施形態)
以下、本発明の第3実施例について図5を参照しながら説明する。
本実施例は、回転子鉄心5の軸方向の両端面に、図5に示す円環状の端板41、42が配置されている。端板41、42は、第1実施例の端板7、8に相当するものであり、外径、内径、及び厚さは端板7、8と略同一である。
(Third embodiment)
The third embodiment of the present invention will be described below with reference to FIG.
In this embodiment, annular end plates 41 and 42 shown in FIG. 5 are arranged on both end faces of the rotor core 5 in the axial direction. The end plates 41 and 42 correspond to the end plates 7 and 8 of the first embodiment, and the outer diameter, inner diameter, and thickness are substantially the same as the end plates 7 and 8.

端板41、42の回転子鉄心5の軸方向の左右両端面と接する面の反対側の面部(外面)には、図5に示すように、内周41a、42aから外周41b、42b側に延びる断面矩形凹状の2つの溝41c、42cが等角度を存して形成されている。該溝41c、42cの外周41b、42b側の開口は、第1実施例の端板7、8と同様に、周方向に拡がり断面矩形凹状の扇形開口部が形成されている(図示せず)。   As shown in FIG. 5, the end plate 41, 42 has a surface portion (outer surface) opposite to the surface in contact with both axial left and right end surfaces of the rotor core 5 from the inner periphery 41a, 42a toward the outer periphery 41b, 42b. Two grooves 41c and 42c having a rectangular concave section extending are formed at equal angles. Similar to the end plates 7 and 8 of the first embodiment, the openings on the outer periphery 41b and 42b side of the grooves 41c and 42c expand in the circumferential direction to form a fan-shaped opening having a rectangular cross section (not shown). .

溝41c、42cの底部の肉厚は、内周41a、42a側では寸法Cとなり、第1実施例の端板7、8と同様であるが、外周41b、42b側へ向かうにつれ肉厚は厚くなるように形成されている。即ち、溝41c、42cは軸方向外方に指向する傾斜状に形成されている。   The thickness of the bottom of the grooves 41c and 42c is the dimension C on the inner circumference 41a and 42a side, which is the same as the end plates 7 and 8 of the first embodiment, but the thickness increases toward the outer circumference 41b and 42b side. It is formed to become. That is, the grooves 41c and 42c are formed in an inclined shape directed outward in the axial direction.

このような本実施例によれば、上記した第1実施例と同様の効果を得ることができ、更に以下の効果を得ることができる。
端板41、42の扇形開口部から噴射飛散された冷却油は、回転周方向に拡がり、更に、軸方向外方へも拡がりながらコイルエンド15aへ向かって飛散される。このため、冷却油はコイルエンド15aの広範囲に亘って散布されるため、より効率良く固定子巻線15を冷却することができる。
According to such a present Example, the effect similar to 1st Example mentioned above can be acquired, and also the following effects can be acquired.
The cooling oil sprayed and scattered from the fan-shaped openings of the end plates 41 and 42 spreads in the rotational circumferential direction, and further splashes toward the coil end 15a while spreading outward in the axial direction. For this reason, since cooling oil is spread over the wide range of the coil end 15a, the stator winding | coil 15 can be cooled more efficiently.

尚、本発明は上記した各実施形態に限定されるものではなく、本願発明の要旨を逸脱しない範囲で適宜変更して実施できる。
例えば、第3実施例を第2実施例に適用してもよい。
上記した第1、及び第2実施例の端板7、8、及び端板41、42は、夫々等角度を存して2本の溝7c、8c、及び溝41c、42cが形成されているが、これに限ることはなく、端板の外面に等角度を存して3本以上の溝が形成されてもよい。
上記実施例として示した電気自動車の回転電機としては、発電機兼用の駆動電動機として用いてもよく、更には電気自動車用に限らず、本発明は回転電機全般に適用可能である。
In addition, this invention is not limited to each above-mentioned embodiment, In the range which does not deviate from the summary of this invention, it can change suitably and can implement.
For example, the third embodiment may be applied to the second embodiment.
The end plates 7 and 8 and the end plates 41 and 42 of the first and second embodiments described above have two grooves 7c and 8c and grooves 41c and 42c formed at equal angles. However, the present invention is not limited to this, and three or more grooves may be formed at an equal angle on the outer surface of the end plate.
The electric rotating machine of the electric vehicle shown as the above-described embodiment may be used as a drive motor that also serves as a generator, and is not limited to an electric vehicle, and the present invention can be applied to general rotating electric machines.

図面中、1、31は機枠、3は固定子、4は回転子、5は回転子鉄心、6は永久磁石、7、8、41、42は端板、9は回転子軸、9a、9bは導入孔、9cは回転子鉄心用噴射孔部、9dは軸受用噴射孔部、12a、12bは案内路、13は固定子鉄心、15は固定子巻線、15aは端部、16a、16bは軸受、19、34は投入口部、21は段部、及び22は空隙路を示す。   In the drawings, 1 and 31 are machine frames, 3 is a stator, 4 is a rotor, 5 is a rotor core, 6 is a permanent magnet, 7, 8, 41 and 42 are end plates, 9 is a rotor shaft, 9a, 9b is an introduction hole, 9c is a rotor core injection hole part, 9d is a bearing injection hole part, 12a and 12b are guide paths, 13 is a stator core, 15 is a stator winding, 15a is an end part, 16a, Reference numeral 16b denotes a bearing, reference numerals 19 and 34 denote inlets, reference numeral 21 denotes a step portion, and reference numeral 22 denotes a gap path.

Claims (4)

機枠と、この機枠の内周部に固定され、固定子巻線を有する固定子と、この固定子の界磁空間に配設された永久磁石形の回転子とを具備してなり、
前記回転子は、
電磁鋼板を積層してなる回転子鉄心と、
この前記回転子鉄心の軸方向の両端面に配置された端板と、
これらの端板及び回転子鉄心の中央部に挿通固定され、両端部が軸受を介して前記機枠に支持された中空状の回転子軸と、
この回転子軸に設けられ、該回転子軸内にその反負荷側の端部から供給された冷却液体を回転遠心力により前記回転子鉄心内面に噴射させる回転子鉄心用噴射孔部と、
前記回転子軸と前記端板の外面とに設けられ、前記回転子軸内に供給された冷却液体を回転遠心力により前記端板の外周側に案内して前記固定子巻線の端部に向け飛散させる案内路と、
を備えて構成されていることを特徴とする回転電機。
A machine frame, a stator having a stator winding fixed to the inner periphery of the machine frame, and a permanent magnet rotor disposed in the field space of the stator;
The rotor is
A rotor core formed by laminating electromagnetic steel sheets;
End plates disposed on both axial end faces of the rotor core;
A hollow rotor shaft that is inserted and fixed in the center part of these end plates and the rotor core, and both end parts are supported by the machine frame via bearings,
An injection hole for a rotor core that is provided on the rotor shaft, and injects a cooling liquid supplied from an end portion on the opposite side of the rotor shaft to the inner surface of the rotor core by a rotational centrifugal force;
Provided on the rotor shaft and the outer surface of the end plate, the cooling liquid supplied into the rotor shaft is guided to the outer peripheral side of the end plate by a rotational centrifugal force to be at the end of the stator winding. A guideway to fly towards,
A rotating electrical machine characterized by comprising:
回転子軸には、該回転子軸内に供給された冷却液体を回転遠心力により軸受に噴射させる軸受用噴射孔部が形成されていることを特徴とする請求項1記載の回転電機。   2. The rotating electrical machine according to claim 1, wherein the rotor shaft is formed with a bearing injection hole for injecting the cooling liquid supplied into the rotor shaft to the bearing by a rotational centrifugal force. 回転子軸は、負荷側の端部が中実状に形成されていることを特徴とする請求項1又は2記載の回転電機。   3. The rotating electrical machine according to claim 1, wherein the rotor shaft has a load-side end formed in a solid shape. 回転子軸の反負荷側の端部内周には、段部が形成されていて、この段部と機枠に設けられた冷却液体投入用の投入口部とで該反負荷側の端部側の軸受に臨む空隙路が形成されていることを特徴とする請求項3記載の回転電機。   A step portion is formed on the inner periphery of the end of the rotor shaft on the side opposite to the load side, and the end portion on the side opposite to the load side is formed between the step portion and a charging liquid inlet port provided in the machine frame. The rotary electric machine according to claim 3, wherein a gap path facing the bearing is formed.
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