JP2011244673A - Split stator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a split stator capable of enhancing motor output.SOLUTION: As a constitution of a split stator, the split stator includes: a yoke section formed with a plurality of yoke pieces, which is annularly arranged and joined to one another; a plurality of teeth joined to a radially inner end of the yoke section; and windings wound around the plurality of teeth by a distributed winding method. Further, it is employed such a constitution for the split stator that each of the plurality of teeth is formed of non-oriented electrical steel sheets and that each of the plurality of yoke pieces is formed of oriented electrical steel sheets having an easy axis of magnetization lying in the same direction as a flow direction of magnetic flux.

Description

 The present invention relates to a split stator.

  In recent years, concentrated winding type synchronous magnet synchronous motors (IPM motors) are often used as motors of several kW class mounted on home appliances and the like. On the other hand, in a high-power IPM motor of several tens of kW class or more, when a concentrated winding method is adopted, in principle, harmonic components are superimposed on the current magnetic field of the stator, and the eddy current of the rotor in which the magnet is embedded is large. Therefore, a distributed winding method in which a harmonic component is not superimposed on the stator current magnetic field tends to be employed.

  Further, in recent years, not only IPM motors but also split stators that can improve the winding space factor and motor efficiency by changing the stator core from a conventional integral core to a split core. It has become mainstream. For example, in Patent Documents 1 to 3 below, a split type in which the stator core is divided into an annular yoke portion and a plurality of teeth portions, and the yoke portion is further divided into a plurality of yoke pieces along the circumferential direction. A stator is disclosed.

JP-A-7-67272 JP 2003-274583 A JP 2006-325296 A

  As the conventional split type stator, as disclosed in Patent Documents 1 to 3, the yoke part is divided into a plurality of yoke pieces, and other than the type using a directional electrical steel sheet for forming the yoke part and the tooth part. The yoke part is divided into a plurality of yoke pieces, a non-oriented electrical steel sheet is used for forming the yoke part, and a directional electrical steel sheet is used for forming the tooth part. The type etc. which use a non-oriented electrical steel sheet for formation and use a directional electrical steel sheet for formation of a tooth part are mentioned.

  What is common to these types of split stators is that a directional electromagnetic steel sheet is used to form the tooth portion, so that the magnetic resistance of the joint portion between the yoke portion and the tooth portion increases and the motor output decreases. This is a problem.

 The present invention has been made in view of the above-described circumstances, and an object of the present invention is to provide a split stator that can improve motor output.

  In order to solve the above-described problem, in the present invention, as a solving means related to the split stator, a yoke part in which a plurality of yoke pieces are joined in an annular shape and a plurality of parts joined radially inward of the yoke part are provided. A tooth portion and a winding wound around the tooth portion in a distributed winding manner, each of the tooth portions is formed using a non-oriented electrical steel sheet, and each of the yoke pieces is a magnetic flux It is formed using a grain-oriented electrical steel sheet having an easy magnetization direction that coincides with the flow direction.

 According to the split stator according to the present invention, since the non-oriented electrical steel sheet is used for forming the tooth portion, the magnetic resistance of the joint portion between the yoke portion and the tooth portion can be reduced, and the motor output can be improved. .

1 is a schematic configuration diagram of a split stator 1 in the present embodiment. It is explanatory drawing regarding the modification which employ | adopted the structure which divides | segments the teeth front-end | tip part 3a from the teeth part 3, and makes this teeth front-end | tip part 3a detachable with respect to the teeth part 3. FIG. It is explanatory drawing regarding the modification which employ | adopted the structure which fixes the yoke part 2 using the winding core 5. FIG. It is explanatory drawing regarding the modification which employ | adopted the structure which fills the clearance gap formed in the junction part 6 of the yoke part 2 and the teeth part 3 with the adhesive agent 7 containing a dust magnetic material.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic configuration diagram of a split stator 1 according to this embodiment. The split stator 1 in this embodiment is a split stator having a winding slot number “12” and a pole number “2”, and a yoke portion 2 formed by joining 12 yoke pieces 2 a in an annular shape, Twelve teeth portions 3 joined (fitted) radially inside the yoke portion 2, and U-phase windings 4Ua, 4Ub, V-phase windings wound around the teeth portions 3 in a distributed winding manner 4Va, 4Vb, and W-phase windings 4Wa, 4Wb.

  Each yoke piece 2a and teeth portion 3 are divided core members formed independently by laminating electromagnetic steel plates made of silicon steel or the like, and are combined with each other to form a single stator core. In the present embodiment, each of the teeth portions 3 is formed using a non-oriented electrical steel sheet, and each of the yoke pieces 2a is in an easy magnetization direction that coincides with the flow direction of magnetic flux (symbol D1 in FIG. 1). It is formed using a grain-oriented electrical steel sheet having (D2 in FIG. 1).

 FIG. 1 shows a state in which one tooth portion 3 is joined to one yoke piece 2a, but a configuration in which a plurality of tooth portions 3 are joined to one yoke piece 2a is adopted. You may do it. Moreover, the yoke part 2 may be formed by joining the yoke pieces 2a to each other by welding, or the yoke part 2 may be formed by fitting the yoke pieces 2a together.

  As shown in FIG. 1, twelve teeth portions 3 are fitted at a constant interval on the radially inner side of the yoke portion 2 (in other words, a pair of teeth portions 3 is formed on the radially inner side of each yoke piece 2a. 1), a total of 12 winding slots S1 to S12 are formed between the adjacent tooth portions 3. One U-phase winding 4Ua is distributedly wound so as to straddle the five tooth portions 3 arranged between the winding slots S1 to S6, and the other U-phase winding 4Ub Distributed winding is performed so as to straddle the five tooth portions 3 arranged between S7 and S12.

  Further, one V-phase winding 4Va is distributedly wound so as to straddle the five teeth portions 3 arranged between the winding slots S3 to S8, and the other V-phase winding 4Vb is wound around Distributed winding is performed so as to straddle the five tooth portions 3 arranged between the line slots S9 to S2. Furthermore, one W-phase winding 4Wa is distributedly wound so as to straddle the five tooth portions 3 arranged between the winding slots S5 to S10, and the other W-phase winding 4Wb Distributed winding is performed so as to straddle the five tooth portions 3 arranged between the line slots S11 to S4.

 According to the split stator 1 in the present embodiment adopting the above-described configuration, since the non-oriented electrical steel sheet is used for forming the tooth portion 3, the joint portion (fitting portion) between the yoke portion 2 and the tooth portion 3 is used. The magnetic resistance can be reduced, and the motor output can be improved.

 Further, in the split stator 1 according to this embodiment, the winding space factor can be improved by changing the stator core from the conventional integral core to the split core, and the flow of magnetic flux in the formation of the yoke portion 2 is improved. Since the grain-oriented electrical steel sheet having the easy magnetization direction D2 that coincides with the direction D1 is used, iron loss can be reduced. Furthermore, the split stator 1 in the present embodiment employs a distributed winding method, and is optimal as a stator for a high-power IPM motor of several tens of kW class or higher.

In addition, this invention is not limited to the said embodiment, The following modifications are mentioned.
(1) In the above embodiment, the split stator 1 having the number of winding slots “12” and the number of poles “2” has been described as an example. However, this is merely an example, and the number of winding slots (the number of teeth 3) The number) and the number of poles can be appropriately changed according to the specifications required for the split stator 1. Further, the number of yoke pieces 2a constituting the yoke portion 2 is not limited to twelve.

(2) As shown in FIGS. 2 (a) and 2 (b), the teeth tip 3 a may be divided from the teeth 3, and the teeth tip 3 a may be detachable from the teeth 3. In this case, the tooth portion 3 is joined to the yoke portion 2 with the teeth tip 3a removed, and the winding slots S1 to S12 are made open slots (see FIG. 2B). Assembly in which the teeth tip 3a is joined (fitted) to the teeth 3 after the U-phase windings 4Ua and 4Ub, the V-phase windings 4Va and 4Vb, and the W-phase windings 4Wa and 4Wb are mounted. The method can be employed, and the winding mounting operation can be facilitated. In addition, you may use any of a directional electrical steel plate and a non-oriented electrical steel plate for formation of this teeth front-end | tip part 3a.

(3) As shown in FIG. 3, the yoke portion 2 is press-fitted into the hollow portion of the wound core 5 in which a directional electromagnetic steel sheet is spirally wound to form a laminated structure, whereby the annular shape of the yoke portion 2 is obtained. A configuration may be adopted in which the yoke portion 2 is fixed while maintaining the above. That is, the winding core 5 may be used as a fixing member for the yoke portion 2 (yoke piece 2a).

(4) As shown in FIG. 4, a gap (gap) of about several hundred μm is formed in the joint portion 6 between the yoke portion 2 (yoke piece 2 a) and the tooth portion 3, and a dust magnetic material is formed in this gap. The yoke part 2 and the teeth part 3 may be bonded together by filling the adhesive 7 containing This powder magnetic material is a powdered magnetic material obtained by crushing and compacting a solid magnetic material, and has the characteristics that the electrical resistance between the powders is large and the eddy current loss (iron loss) is small. is doing. That is, by filling the gap 7 formed in the joint 6 with the adhesive 7 containing such a dust magnetic material, while avoiding an interlayer short circuit between the yoke part 2 and the tooth part 3 (eddy current due to the interlayer short circuit) While avoiding the occurrence), it is possible to reduce the magnetic resistance of the joint 6, and as a result, it is possible to obtain the split stator 1 capable of avoiding a decrease in motor output and an increase in iron loss.

  DESCRIPTION OF SYMBOLS 1 ... Split-type stator, 2 ... Yoke part, 2a ... York piece, 3 ... Teeth part, 3a ... Teeth tip part, 4Ua, 4Ub ... U-phase winding, 4Va, 4Vb ... V-phase winding, 4Wa, 4Wb ... W Phase winding, 5 ... winding core, 6 ... joint, 7 ... adhesive, S1-S12 ... winding slot

Claims (1)

A yoke part in which a plurality of yoke pieces are joined in an annular shape;
A plurality of teeth joined to the inside of the yoke in the radial direction;
A winding wound in a distributed winding manner on the teeth part,
Each of the teeth portions is formed using a non-oriented electrical steel sheet,
Each of the yoke pieces is formed using a grain-oriented electrical steel sheet having an easy magnetization direction that coincides with the direction of flow of magnetic flux.

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