Patent Abstract:
A motor includes a rotor with interior permanent magnets and a stator with teeth wound by concentrated windings. Each permanent magnet is split along a plane oriented towards the stator, and an electrically insulating section is set between the split magnet pieces. This structure allows each permanent magnet to be electrically split, thereby restraining the production of an eddy current. As a result, heat-production is dampened thereby preventing heat demagnetization of the permanent magnets.

Full Description:
This application is a divisional of U.S. application Ser. No. 09/471,375, filed Dec. 23, 1999. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates generally to a motor having a rotor with interior permanent magnets, more particularly it relates to a motor with interior split-permanent-magnets, such that it restrains eddy-currents from occurring and prevents demagnetization of the magnets. 
     BACKGROUND OF THE INVENTION 
     FIG. 11 illustrates a rotor with interior permanent magnets of a conventional motor. The motor has rotor  310  in which permanent magnets  312  are embedded, and rotor  310  is disposed in a stator (not shown) with concentrated wounds, so that the motor can be driven by not only magnet torque but also reluctance torque. This rotor is hereinafter referred to as a “rotor with interior permanent magnets”. 
     However this conventional motor has the following problems: 
     Compared with a motor with a distributed-wound stator, a motor with a concentrated-wound stator subjects itself to greater changes of magnetic flux interlinked with rotor  310  when the motor rotates. As a result, a large-eddy-current occurs in magnets  312  embedded in the rotor, and thus the motor with a concentrated-wound stator is vulnerable to irreversible demagnetization of the magnets. Meanwhile, the distributed-wound stator is structured in the following way: A slot is formed between two stator-teeth, and a plurality of teeth thus form a plurality of slots. Wounds striding over at least one slot are provided, and part of a wound of a phase exists between pitches of another phase wound. The concentrated-wound stator, on the other hand, is structured by providing a wound of one phase to one stator tooth respectively. 
     The reason why the motor having the concentrated-wound stator is vulnerable to demagnetization is detailed hereinafter. 
     It is well known that eddy current lost “W c ” is proportionate to a square of maximum operable magnetic-flux density “B m ”, and this relation can be expressed in the following equation. 
     
       
           W   c   P   t   /t={ ⅙ρ)}π 2   f   2   B   m   2   t   2    [W/m   3 ] 
       
     
     wherein P t =power consumption 
     t=plate width interlinking with the magnetic flux 
     ρ=resisting value proper to the permanent magnet 
     f=exciting frequency 
     Since the motor having the concentrated-wound stator is subjected to greater changes in magnetic flux running through the rotor, the maximum operable magnetic-flux density “B m ” in the above equation becomes greater and thus eddy-current loss “W c ” grows larger. 
     If a motor has the concentrated-wound stator, and yet, the permanent magnets are struck onto an outer wall of the rotor, the changes in magnetic-flux-density is not so large that the demagnetization of the magnets due to the eddy-current loss is negligible. In the motor having the concentrated-wound stator and a rotor in which the permanent magnets are embedded, the space between the magnet and the outer circumference of rotor core  314  forms a path for the magnetic-flux to flow. The density of magnetic-flux from the stator changes depending on the position of stator teeth with regard to the magnets, so that magnitude of changes in the magnetic-flux-density at the path is increased. As a result, eddy-current occurs in the magnets  312  embedded in rotor  310 , thereby heating the magnet to produce irreversible magnetization of the magnet. 
     SUMMARY OF THE INVENTION 
     The present invention addresses the problems discussed above and aims to provide a motor having a rotor with interior-permanent-magnets. This rotor produces less eddy-current and can prevent demagnetization of the permanent magnets embedded in the rotor. 
     The motor of the present invention comprises the following elements: 
     a rotor in which permanent magnets are embedded, and 
     a stator of which teeth are wound by wounds in a concentrated manner. 
     The permanent magnets are split into magnet pieces, and insulating sections are inserted into respective gaps between respective magnet pieces. This structure splits the magnets electrically, thereby restraining the eddy-current from occurring and then suppressing the demagnetization of the magnets embedded in the rotor. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a cross-sectional view illustrating a motor, having a rotor with interior permanent magnets, in accordance with a first exemplary embodiment of the present invention. 
     FIG. 2 is a perspective view of the permanent magnets to be embedded into the rotor of the motor shown in FIG.  1 . 
     FIG. 3 is a perspective view of permanent magnets to be embedded into a rotor of a motor in accordance with a second exemplary embodiment of the present invention. 
     FIG. 4 is a perspective view of permanent magnets to be embedded into a rotor of a motor in accordance with a third exemplary embodiment of the present invention. 
     FIG. 5 is a cross-sectional view illustrating a rotor of a motor, in which “I” shaped permanent magnets are embedded, in accordance with a fourth exemplary embodiment of the present invention. 
     FIG. 6 is a cross-sectional view illustrating a rotor of a motor, in which permanent magnets are embedded, in accordance with a fifth exemplary embodiment. 
     FIG. 7A is a perspective view of permanent magnets to be embedded into the rotor of the motor in accordance with the fifth exemplary embodiment. 
     FIG. 7B is a front view of the permanent magnets shown in FIG.  7 A. 
     FIG. 8A is a perspective view of permanent magnets to be embedded into a rotor of a motor in accordance with a sixth exemplary embodiment. 
     FIG. 8B is a front view of the permanent magnets shown in FIG.  8 A. 
     FIG. 9 is a perspective view of permanent magnets to be embedded into a rotor of a motor in accordance with a seventh exemplary embodiment. 
     FIG. 10 is a block diagram of an electric vehicle in which the motor of the present invention is mounted. 
     FIG. 11 is a cross-sectional view illustrating a conventional motor having a rotor with interior permanent magnets. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     Exemplary embodiments of the present invention are demonstrated hereinafter with reference to the accompanying drawings. 
     (Exemplary Embodiment 1) 
     FIG. 1 is a cross sectional view illustrating a motor, having a rotor with interior permanent magnets, in accordance with the first exemplary embodiment of the present invention, and FIG. 2 is a perspective view of the permanent magnets to be embedded into the rotor of the same embodiment. 
     In FIG. 1, motor  10  includes a rotor  14  with interior permanent magnets  12 , and stator  15  facing the rotor  14  via an annular space. Respective teeth  17  of stator  15  are wound by wounds  18  in a concentrated manner, i.e. concentrated wounds are provided on respective teeth. 
     Rotor  14  comprises the following elements: 
     a rotor core laminated with a plurality of steel plates; 
     permanent magnets  12  embedded into slots axially provided; and 
     a rotating shaft  16  extending through a center of the rotor core. Thus, the rotating shaft  16  provides the rotor  14  with an axis of rotation. 
     Respective magnets  12  have a shape protruding toward the center of the rotor core. As such, the magnets are embedded in the rotor so that rotor  4  can produce respective directions for magnetic flux to flow with ease and with difficulty. An inductance ratio in respective directions can be thus obtained, and it is called a salient pole rate. 
     A rotor polarity is formed between magnets  12  and an outer wall of the rotor core which magnets  12  face. The magnetic-flux from a permanent magnet flows with ease through the section covering the rotor polarity, and this flowing direction is called “d axis”. On the other hand, the magnetic-flux flows with difficulty through a section covering a boundary between two adjacent magnets, and this flowing direction is called “q axis”. 
     Stator  15  is formed by linking twelve stator-blocks  19  to each other in an annular shape. Each stator block  19  comprises teeth  17  wound by wounds  18  in the concentrated manner, and the blocks are welded to form a ring. In the case of a three-phase and eight-pole motor, for instance, wounds are provided on a first four teeth, and these teeth are coupled with each other thereby forming phase “U”. In the same manner, the wounds provided on the second four teeth on the right side of the respective first four teeth discussed above are coupled with each other thereby forming phase “V”. Further, the wounds provided on the third four teeth on the left side of the first four teeth are coupled with each other thereby forming phase “W”. Stator  15  thus forms three-phase with concentrated wounding. 
     In motor  10  constructed above, the magnetic flux generated by magnet  12 , i.e. the magnetic flux produced by the rotor-magnetic-poles, travels to teeth  17  of the stator via the annular space thereby contributing to the torque production. This motor has the salient-pole-rate and controls the current-phases to be optimal by current, thereby driving itself not only by the magnet torque but also by the reluctance torque. 
     One of the features of the present invention is a method of embedding the permanent magnets into the rotor. Magnets  12  to be embedded into rotor  14  in the first exemplary embodiment are detailed hereinafter. 
     As shown in FIG. 2, each magnet  12  is split into two magnet pieces  13  in the axial direction of rotor  14 . In other words, the two magnet pieces  13  are separated from one another along a plane that does not extend traverse to the axis of rotation of the rotor. Each two magnet pieces  13  are embedded into one single hole provided in rotor  14 , thereby forming each magnet  12 . Epoxy resin of an electrically insulating type, used as a coating material, is applied to the overall surface of each magnet piece  13 . If magnet pieces  13  are stacked-up, each piece is electrically insulated and they can form an independent circuit. A space between respective stacked-up magnet pieces  13  is not less than 0.03 mm, corresponding to the thickness of coating material applied to the magnet pieces. 
     The two magnet pieces  13  are embedded adjacently with each other into the hole of the rotor core so that magnet  12  is split into two sections facing stator  15 . Respective magnet pieces  13  are arranged in the following way: 
     Respective magnetic-fluxes generated from two magnet pieces embedded in one hole flow in the same direction with regard to the outer wall of the rotor to which these two magnet pieces face. Another pair of magnet pieces embedded in a hole adjacent to the hole discussed above generate the magnetic flux in the direction reversed to the direction of the magnetic flux discussed above. For instance, two magnetic pieces embedded in one hole face the outer wall of the rotor with poles “N”, then another pair of magnet pieces embedded in the hole adjacent to this hole should face the outer wall with poles “S”. 
     The space between the two magnet pieces is not necessarily filled with resin, and it can be filled with any electrically-insulating-material, or can include an air-gap. 
     Magnet  12  is split by a plane facing toward stator  15 , thereby reducing the eddy current produced in magnet  12 . The plane extends from the rotor center toward the stator. This is because of the following reason: 
     Since teeth  17  are wound by concentrated wounds  18 , stator  15  receives greater changes in the density of magnetic-flux supplied from teeth  17 . The maximum operable magnetic-flux-density B m  expressed in the equation discussed previously thus grows greater. This change in the magnetic-flux density produces the eddy current in each magnet  12 . In this first exemplary embodiment, each magnet  12  embedded in rotor  14  is split into two magnet pieces  13 , and epoxy resin, which is non-magnetic material, is put between these two pieces, thereby dividing magnet  12  not only physically but also electrically. As a result, the production of an eddy current is restrained by narrowing the width “t” of a plate interlinking with the magnetic flux in the equation discussed previously. 
     (Exemplary Embodiment 2) 
     FIG. 3 is a perspective view of permanent magnets to be embedded into a rotor of a motor in accordance with the second exemplary embodiment of the present invention. This second embodiment differs from the first one in the way of splitting the magnet; and otherwise remains the same. 
     In the first embodiment, the magnet is split into two pieces in the axial direction, however magnet  22  in this second embodiment is split into five pieces in the axial direction, and this produces the same advantage as produced in the first embodiment. 
     (Exemplary Embodiment 3) 
     FIG. 4 is a perspective view of permanent magnets to be embedded into a rotor of a motor in accordance with the third exemplary embodiment of the present invention, This third embodiment differs from the first one in the way of splitting the magnet, and otherwise remains the same. 
     In the first embodiment, the magnet is split into two pieces in the axial direction, however magnet  32  in this third embodiment is split into three pieces in a vertical direction with regard to the axial direction, and this produces the same advantage as produced in the first embodiment. 
     The first, second and third embodiments prove that the magnets split into pieces along planes facing the stator can restrain the production of eddy currents. 
     (Exemplary Embodiment 4) 
     FIG. 5 is a cross section illustrating a rotor of a motor, in which “I” shaped permanent magnets are embedded, in accordance with the fourth exemplary embodiment of the present invention. This fourth embodiment differs from the previous embodiments 1-3 in the shape of magnet. In the previous embodiments, the magnet is in a “V” shape, however, magnet  42  in the fourth embodiment is shaped like the letter “I”. 
     In FIG. 5, each magnet  42  formed by two magnet pieces aligned in an “I” shape is inserted into each hole provided in rotor  44 . Electrically insulating material is put between the two pieces, or an air gap can be used to electrically insulate the two pieces. The fourth embodiment can produce the same advantage as produced in the first embodiment. 
     Regarding the shape of the magnet, the embodiments 1-3 employ a “V” shape, and this fourth embodiment employs an “I” shape, however, the shape can be an are being bowed toward the rotor center. 
     (Exemplary Embodiment 5) 
     FIG. 6 is a cross sectional view illustrating a rotor of a motor, in which permanent magnets are embedded, in accordance with the fifth exemplary embodiment. FIG. 7A is a perspective view of the permanent magnets to be embedded into the rotor of the motor in accordance with the fifth exemplary embodiment, and FIG. 7B is a front view of the permanent magnets shown in FIG.  7 A. 
     In FIG. 6, permanent magnets  52  are embedded in rotor  54 , and rotary shaft  56  extends through the rotor center. This motor has a stator (not shown) disposed around rotor  54  via an annular space. 
     Magnet  52  is formed by laminating a plurality of rare-earth-sintered magnet pieces. Air gaps  58  are provided between respective magnetic pieces. Magnet  52  is bowed toward the rotor center. 
     Magnet  52  is further detailed with reference to FIGS. 7A and 7B. 
     Magnet  52  comprises  52  comprises a rare-earth-sintered magnet. In general, the rare-earth-sintered magnet is coated on its surface in order to avoid corrosion. Magnet  52  is formed by laminating six pieces of this rare-earth-sintered magnet. Two or more than two protrusions are provided on the respective faces laminated so that air gaps  58 , as insulating layers, are provided for each magnet piece. The total area of the protrusions formed on each magnet piece should be smaller than the area of the face laminated, e.g. not more than 10% of the face laminated. The number of magnet pieces is not limited to six but other plural numbers are acceptable as far as they can provide air gaps between each magnet piece. 
     As such, since magnet  52  has insulating layers (air gaps) between respective magnet pieces making up magnet  52 , it is difficult for current to run through magnet  52 . As a result, the production of an eddy current is restrained. Meanwhile, magnet  52  employs a conductive coating material to avoid corrosion, however, the material can be an insulating one, or further, respective air gaps can be filled with insulating resin thereby enhancing the strength of magnet  52 . The protrusions formed on each magnet piece can be made from another material and disposed on each magnet piece. Electrically insulating material among others for forming the protrusions can produce the advantage distinctly. 
     (Exemplary Embodiment 6) 
     FIG. 8A is a perspective view of permanent magnets to be embedded into a rotor of a motor in accordance with the sixth exemplary embodiment, and FIG. 8B is a front view of the permanent magnets shown in FIG.  8 A. 
     This sixth embodiment differs from the fifth one in the way of splitting the magnet, and otherwise remains the same. 
     In the fifth embodiment, the magnet is split into six pieces in the axial direction, however, magnet  62  in this sixth embodiment is split into three pieces in a vertical direction with regard to the axial direction. The sixth embodiment can produce the same advantage as produced in the fifth one. 
     (Exemplary Embodiment 7) 
     FIG. 9 is a perspective view of permanent magnets to be embedded into a rotor of a motor in accordance with the seventh exemplary embodiment of the present invention. 
     This seventh embodiment differs from the fifth one in the way of splitting the magnet, and otherwise remains the same. 
     In the fifth embodiment, the magnet is split into six pieces in the axial direction, however, magnet  72  in this seventh embodiment is split into three pieces in a rotating direction, and a center piece of the three pieces is further split into five pieces in the axial direction. The seventh embodiment can produce the same advantage as produced in the fifth one. 
     When rare-earth-sintered magnets are used as interior permanent magnets in the rotor, splitting the magnet affects the advantage distinctly because a rare-earth-sintered magnet has less electrical resistance and, it is easier for current to run therethrough as compared to a ferrite magnet. (The specific resistance of the ferrite magnet is not less than 10− 4 Ω·m, and that of the rare-earth-sintered magnet is not less than 10− 6 Ω·m.). In other words, when the same magnitude of change in the magnetic-flux-density is applied from outside to the magnet, the rare-earth-sintered magnet allows the eddy current to run through more than 100 times in volume than the ferrite magnet does. Thus the split of such a magnet effectively restrains the production of an eddy current. 
     A driving control of the motor is demonstrated hereinafter, which motor includes the rotor with the interior magnets of the present invention. 
     A motor with a stator wound by concentrated wounds produces greater changes in the magnetic-flux-density when the motor is driven under a magnetic-field control. In the motor having a rotor with interior permanent magnets, the magnetic-flux runs through the space between the magnets and the outer circumference of the rotor core, and thus the magnetic-flux is distributed unevenly between the rotor and the stator. 
     The magnetic-field control applies an inverse magnetic-field to the motor so that the magnetic-flux produced by the magnet can be counteracted, and therefore, this control method produces greater changes in the magnetic-flux than does a regular control method. Further, the inverse magnetic-field narrows tolerance for irreversible demagnetization, and this produces a possibility of demagnetization at a temperature which is a matter of little concern in a normal condition. The magnetic-field-control thus produces distinctly an advantage of damping the heat generated by the eddy current. 
     It is preferable to restrain the production of an eddy current as well as the heat-generation from the eddy current by splitting the magnet, and this shows distinctly its effect when the motor is under magnetic-field-control. 
     The motor used in the embodiments discussed above is an inner-rotor type, i.e. a rotor is disposed inside a stator, however, an outer-rotor type, i.e. a rotor is disposed outside a stator, and a linear motor, i.e. a rotor moves linearly with regard to a stator, produce the same advantages. 
     As the exemplary embodiments discussed previously prove that the motor with interior permanent magnets of the present invention can restrain the production of an eddy current and dampen the demagnetization, because the magnet is electrically split and thus an area of each magnet facing the stator becomes narrower. The motor under the magnetic-field control can further dampen the demagnetization. 
     (Exemplary Embodiment 8) 
     FIG. 10 is a block diagram of an electric vehicle in which the motor of the present invention is mounted. 
     Body  80  of the electric vehicle is supported by wheels  81 . This vehicle employs a front-wheel-drive method, so that motor  83  is directly connected to front-wheel-shaft  82 . Motor  83  includes a stator wound by concentrated wounds and having interior permanent magnets as described in the exemplary embodiments previously discussed. Controller  84  controls the driving torque of motor  83 , and battery  85  powers controller  84  and further powers motor  83 . Motor  83  is thus driven, which then rotates wheels  81 . 
     In this eighth embodiment, the motor is employed to drive the wheels of the electric vehicle. The motor can be employed also to drive wheels of an electric locomotive.

Technology Classification (CPC): 8