JP4113353B2 - Rotating electric machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention comprises a rotating electric machine, in particular, a plurality of small permanent magnets having a rectangular parallelepiped shape to form a magnetic pole, which improves magnetic flux distribution and reduces leakage magnetic flux by its magnetization method, and exhibits various characteristics with a simple structure. The present invention relates to a rotating electrical machine including a rotor using a permanent magnet and a stator that can easily wind a rectangular conductor wire with a good space factor with a simple structure.
[0002]
[Prior art]
In recent years, various rotating electrical machines using permanent magnets have been proposed. For example, in a conventional rotating electric machine using permanent magnets for driving automobile wheels, a number of permanent magnets corresponding to the number of magnetic poles are provided one by one on the circumferential surface of the rotor or in the vicinity of the circumferential surface.
[0003]
Further, the rotor 51 of the conventional magnet embedded type reluctance motor has a structure in which a permanent magnet 53 is embedded in the middle of the rotor core 52 as shown in FIG.
[0004]
[Problems to be solved by the invention]
In a conventional rotor in which the number of permanent magnets corresponding to the number of magnetic poles is embedded one by one on the circumferential surface of the rotor or in the vicinity of the circumferential surface, the single arcuate permanent magnet to be arranged has a large magnetic pole surface, which is caused by eddy currents. The eddy current loss is large, and the magnetic flux distribution on the rotor surface of the permanent magnet becomes trapezoidal as shown by the dotted line in FIG. 4, and the torque generated in the motor pulsates, generating magnetic noise. It was not preferable as.
[0005]
Further, in the structure of the conventional rotor 51 as shown in FIG. 23 in which the permanent magnet 53 of the embedded magnet type reluctance motor is embedded, the centrifugal load is concentrated on the end of the permanent magnet 53 when rotating at a high speed, and the dotted line in FIG. There was a possibility that the part indicated by the circle of would be destroyed.
[0006]
  The present invention has been made in view of the above points, and by forming a magnetic pole using a plurality of small cuboid permanent magnets and considering the magnetization direction, the eddy current loss is reduced and the magnetic flux distribution is reduced. Improvement and reduction of leakage magnetic flux, simple structure, various characteristics, and structure that does not break with centrifugal forceWhen equipped with a rotorAnother object of the present invention is to provide a rotating electrical machine including a stator that can easily wind a rectangular wire with a good space factor with a simple structure.
[0007]
[Means for Solving the Problems]
  In order to solve the above-described object, a rotating electrical machine according to the present invention is provided in a rotor having a structure including a rotating shaft, a rotor core attached to the rotating shaft, and a permanent magnet fixed to the rotor core, a stator ring, and a stator ring. In the rotating electrical machine having a tee score and a stator having a structure having a stator coil wound around the tee score, the rotor has a predetermined interval in the circumferential direction and a plurality of permanent portions along the rotation axis direction. A rotor laminated core provided with magnet grooves, a plurality of cuboid permanent magnets arranged in parallel to the permanent magnet grooves and constituting magnetic poles, and a plurality of cuboid permanent magnets arranged in parallel to the permanent magnet grooves are arcuate. And a non-conductive space material for positioning the rectangular parallelepiped permanent magnets arranged between adjacent rectangular parallelepiped permanent magnets, The rectangular parallelepiped permanent magnets arranged side by side in a bow shape in the groove for use are magnetized in the same direction and strongly magnetized from both ends toward the center, and a plurality of rectangular solid permanent magnets arranged in the permanent magnet groove The rotor has a magnetic flux distribution on the surface of the rotor made of magnets and the sine wave of the magnetic flux distribution on the surface of the rotor.For each tea score provided on the stator ring,From the tip of the tea score toward the base, the thickness of each laminated coil is reduced and the coil width is increased, and the cross-sectional area of each laminated layer coil is constant.Formed and the winding structure of the coil is an aligned vertical windingIt is characterized by that.
[0008]
  AndThe rotating electrical machine of the present invention includes a rotor having a structure including a rotating shaft, a rotor core attached to the rotating shaft, and a permanent magnet fixed to the rotor core, a stator ring, a tee score provided on the stator ring, and a winding around the tee score. In a rotating electrical machine having a stator having a structure having a stator coil to be rotated, the rotor has a predetermined interval in the circumferential direction and a plurality of grooves for permanent magnets provided in the rotation axis direction. Adjacent to the laminated core, a plurality of rectangular parallelepiped permanent magnets arranged in parallel in the permanent magnet groove, and a plurality of rectangular parallelepiped permanent magnets arranged in parallel in the permanent magnet groove. And a non-conductive space material for positioning the rectangular parallelepiped permanent magnets, and arranged in parallel in a bow shape in the grooves for the permanent magnets. Of the cuboid permanent magnets constituting the magnetic poles, the magnetization direction of the cuboid permanent magnets at both ends thereof is magnetized in a direction perpendicular to the magnetization direction of the adjacent cuboid permanent magnets magnetized in the same direction. And a stator coil that reduces d-axis leakage of magnetic flux from magnetic poles formed by a plurality of rectangular parallelepiped permanent magnets arranged in the groove, and the stator coil of the stator is provided for each tee score provided in the stator ring. The thickness of each laminated coil is made thin and the coil width is widened from the tip of the tea score toward the base, and the cross-sectional area of each laminated layer coil is constant. The winding structure of the coil is an aligned vertical windingIt is characterized by that.
[0009]
  AndThe rotating electrical machine of the present invention includes a rotor having a structure including a rotating shaft, a rotor core attached to the rotating shaft, and a permanent magnet fixed to the rotor core, a stator ring, a tee score provided on the stator ring, and a winding around the tee score. In a rotating electrical machine having a stator having a structure having a stator coil to be rotated, the rotor has a predetermined interval in the circumferential direction and a plurality of grooves for permanent magnets provided in the rotation axis direction. Adjacent to the laminated core, a plurality of rectangular parallelepiped permanent magnets arranged in parallel in the permanent magnet groove, and a plurality of rectangular parallelepiped permanent magnets arranged in parallel in the permanent magnet groove. And a non-conductive space material for positioning the rectangular parallelepiped permanent magnets, and arranged in parallel in a bow shape in the grooves for the permanent magnets. All the rectangular parallelepiped permanent magnets are magnetized in the same direction, and a rotor for generating reluctance torque is formed by the space between adjacent permanent magnet grooves of magnetic poles constituted by a plurality of rectangular parallelepiped permanent magnets. The stator coil of the stator has a thickness that is reduced for each of the tee scores provided on the stator ring as the thickness of each of the stacked coils decreases from the tip of the tee score toward the base. Is formed widely, and the cross-sectional area of the coil of each laminated layer is formed to be constant, and the winding structure of the coil is an aligned vertical windingIt is characterized by that.
[0010]
  The rotating electric machine of the present invention includes a rotor having a structure including a rotating shaft, a rotor core attached to the rotating shaft, and a permanent magnet fixed to the rotor core, a stator ring, a tee score provided on the stator ring, and a wrap around the tee score. In a rotating electrical machine having a stator having a structure having a stator coil to be rotated, the rotor is arranged in parallel on a rotor laminated core in which a plurality of rectangular parallelepiped permanent magnets are arranged in parallel on the entire circumferential surface, and on the entire circumferential surface. A rectangular solid permanent magnet arranged between adjacent rectangular parallelepiped permanent magnets for arranging a rectangular parallelepiped permanent magnet fixing member for fixing a rectangular parallelepiped permanent magnet and a rectangular parallelepiped permanent magnet arranged in parallel on the peripheral surface of the rotor laminated core in an annular shape. And a non-conductive space material for positioning the magnetic poles, and the magnetic poles arranged in parallel in a ring shape on the peripheral surface of the rotor laminated core A plurality of cuboid permanent magnets constituting the magnet are magnetized in the same direction in the cuboid permanent magnet in the central portion, and gradually become smaller in the magnetization direction of the cuboid permanent magnet in the central portion as approaching both ends. The cuboid permanent magnet that is the boundary of the magnet is magnetized in a direction perpendicular to the magnetization direction of the adjacent cuboid permanent magnets, and the magnetic flux distribution on the rotor surface of the magnetic pole constituted by the plurality of cuboid permanent magnets is sinusoidal. A stator coil of a stator having a wavy rotor,For each tea score provided on the stator ring,From the tip of the tea score toward the base, the thickness of each laminated coil is reduced and the coil width is increased, and the cross-sectional area of each laminated layer coil is constant.Formed and the winding structure of the coil is an aligned vertical windingIt is characterized by that.
[0011]
And said rectangular parallelepiped permanent magnet may be comprised with the some small permanent magnet each laminated | stacked on the rotating shaft direction and its radial direction.
[0012]
  The rotating electric machine of the present inventionOf the stator according toThe stator coil is formed such that the thickness of each laminated coil is thinned and the coil width is widened from the tip of the tea score toward the base portion, and the coil of each laminated layer is formed. The cross-sectional area is formed to be constant.
[0013]
  AndThe stator according to the rotating electrical machine of the present inventionThe stator ring is provided with a plurality of fitting grooves at equal intervals on the inner peripheral surface thereof, and the teascore has a stator tooth formed on one side thereof and a fitting provided on the inner peripheral surface of the stator ring on the other side. A fitting portion to be engaged with the groove is formed, and the fitting portion of the tee score is fitted into the fitting groove of the stator ring to constitute the stator core.
[0014]
  By using a plurality of cuboid permanent magnets having a structure in which the permanent magnets constituting the magnetic poles of the rotor are divided, the eddy current loss can be reduced, and the direction of magnetization of the plurality of cuboid permanent magnets constituting the magnetic poles By appropriately adjusting the size of the rotor, it is possible to improve the magnetic flux distribution and reduce the leakage magnetic flux, and to achieve a rotor that exhibits various characteristics with a simple structure.In addition, the structure that attaches the tee score to the stator ring makes it easy to wind the stator coil around the stator with a good space factor, and the stator core also has a structure in which the tee score is fitted and fixed to the stator ring. The stator coils can be individually wound and formed, and these assemblies can be assembled in a short time.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is a configuration diagram of an embodiment of a rotor used in the rotating electrical machine of the present invention, FIG. 2 is an explanatory diagram of an embodiment configuration of a rectangular parallelepiped permanent magnet constituting a magnetic pole, and FIG. 3 is an arcuate parallelepiped permanent magnet arranged in parallel. An example of the arrangement of the space material according to one embodiment is shown.
[0016]
1 to 3, a rotor laminated core 3 is attached to the rotary shaft 2 of the rotor 1, and the rotor laminated core 3 has a predetermined interval in the circumferential direction in the vicinity of the outer periphery of the rotor laminated core 3. A plurality of permanent magnet grooves 4 along the direction are provided, for example, eight in FIG.
[0017]
Each permanent magnet groove 4 is provided in an arc shape, and 17 rectangular parallelepiped permanent magnets 5 are accommodated in a parallel arrangement (an arcuate formation parallel arrangement as will be described below). .
[0018]
The rectangular parallelepiped permanent magnet 5 has a rectangular cross section, and between the adjacent rectangular parallelepiped permanent magnets 5, a non-conductive space material 6 having a wedge shape on the outer peripheral side from the center of the rotating shaft 2 extends along the rotating shaft 2 direction. As shown in FIG. 3, each of the 17 rectangular parallelepiped permanent magnets 5 is formed in an arcuate shape, that is, in an arcuately formed parallel arrangement, and the space member 6 positions each rectangular parallelepiped permanent magnet 5. .
[0019]
Then, the hybrid permanent magnets of the 17 rectangular parallelepiped permanent magnets 5 and the 16 space members 6 arranged in parallel in an arcuate shape are fixed to the permanent magnet grooves 4 provided in the rotor laminated core 3 by fixing means such as press fitting. It is attached to the rotor laminated core 3 and constitutes the magnetic poles of the rotor 1.
[0020]
FIG. 5 is an explanatory diagram of magnetization of rectangular parallelepiped permanent magnets arranged in an arcuate shape.
[0021]
In the same figure, the direction and length of the arrow indicate the direction and size of magnetization, and as indicated by the length of the arrow, in the vicinity of the center position of the 17 cuboid permanent magnets 5 illustrated above. The arranged rectangular parallelepiped permanent magnet 5 is strongly magnetized, the residual magnetic flux density is high, and is weakly magnetized toward both ends thereof, and the residual magnetic flux density is lowered. The rectangular permanent magnets 5 at both ends are magnetized in the directions shown in FIG.
[0022]
The rectangular parallelepiped permanent magnets 5 arranged in an arcuate shape in the direction and size of the arrow shown in FIG. 5 are magnetized, and in the case shown in FIG. By magnetizing the plurality of cuboid permanent magnets 5 constituting the magnetic pole shown in FIG. 1 as described above, it is possible to alternately form N-pole and S-pole magnetic poles.
[0023]
The magnetic flux distribution on the surface of the rotor 1 of each of the magnetic poles N and S is shown by a solid line in FIG. 4 as compared with a conventional trapezoidal magnetic flux distribution by a single permanent magnet shown by a dotted line in FIG. As shown, it is improved to a sine wave. Therefore, the pulsation of torque generated in the motor is reduced. Further, due to the magnetization direction of each of the rectangular parallelepiped permanent magnets 5 at both ends, the magnetic path between the adjacent rectangular parallelepiped permanent magnets 5 constituting the adjacent magnetic pole is saturated, and the magnetic flux of the magnetic pole becomes difficult to leak and leakage of the magnetic flux is prevented. Can be reduced.
[0024]
Moreover, when the eddy current loss is divided into n, (I / n)²・ R ・ n = 1 / n ・ I²R and loss is 1 / n.
[0025]
A magnetic pole configuration in which the rectangular parallelepiped permanent magnets 5 at both ends are omitted may be used.
[0026]
In the above description, the rotor 1 having a structure in which the rectangular parallelepiped permanent magnet 5 is embedded in the permanent magnet groove 4 provided in the rotor laminated core 3 has been described. However, as described later with reference to FIG. A rectangular parallelepiped permanent magnet 5 may be disposed in the permanent magnet groove 4 and the cylindrical member may be covered thereon.
[0027]
FIG. 6 is a diagram illustrating the configuration of an example of a rectangular parallelepiped permanent magnet using a small permanent magnet. The rectangular parallelepiped permanent magnet 5 divides the rectangular parallelepiped permanent magnet 5 shown in FIG. 2 in the direction of the rotary shaft 2 and the radial direction thereof. In other words, it has a structure in which cubic small permanent magnets 7 are stacked, and eight small permanent magnets 7 are stacked in the direction of the rotating shaft 2 and four small permanent magnets 7 are stacked in the radial direction. It is shown. The magnets are magnetized in the direction shown in FIG.
[0028]
Since the rectangular parallelepiped permanent magnet 5 composed of eight small permanent magnets 7 in the direction of the rotating shaft 2 and four in the radial direction thereof can have the same shape as the rectangular parallelepiped permanent magnet 5 shown in FIG. The description of the attachment to the rotor laminated core 3 is omitted.
[0029]
FIG. 7 shows an explanatory diagram of magnetization of a rectangular parallelepiped permanent magnet by a small permanent magnet.
[0030]
Even when the rectangular parallelepiped permanent magnet 5 is composed of a plurality of small permanent magnets 7, the method of magnetization is the same as that described with reference to FIG.
[0031]
Also in this case, similarly to FIG. 5, a magnetic pole configuration in which the rectangular parallelepiped permanent magnets 5 at both ends are omitted may be used.
[0032]
As described above, the rectangular parallelepiped permanent magnet 5 composed of a large number of inexpensive and simple rectangular parallelepiped permanent magnets 5 and small permanent magnets 7 is formed in the permanent magnet groove 4 on the peripheral surface of the rotor laminated core 3 or in the vicinity of the peripheral surface. By arranging and changing the magnetization direction or magnet material of the individual rectangular parallelepiped permanent magnets 5, the magnetic characteristics of the rotor 1 can be varied in many ways.
[0033]
In addition, by using a non-conductive material for the space member 6 placed between adjacent rectangular parallelepiped permanent magnets 5, eddy current loss generated on the magnetic pole surface of the magnetic pole composed of a plurality of rectangular solid permanent magnets 5 is reduced. Can be reduced.
[0034]
FIG. 8 shows a configuration diagram of another embodiment of a rotor used in the rotating electrical machine of the present invention.
[0035]
In this figure, the mechanical configuration of the rotor 11 is the same as that of the rotor 1 shown in FIG. That is, the rotor laminated core 3 is attached to the rotating shaft 2 of the rotor 11, and the rotor laminated core 3 has a predetermined interval in the circumferential direction near the outer periphery thereof and is permanent along the direction of the rotating shaft 2. A plurality of, for example, eight magnet grooves 4 are provided.
[0036]
Each permanent magnet groove 4 is provided in an arcuate shape, and 17 rectangular parallelepiped permanent magnets 5 are accommodated in a parallel arrangement.
[0037]
The rectangular parallelepiped permanent magnet 5 has a rectangular cross section, and between the adjacent rectangular parallelepiped permanent magnets 5, a non-conductive space material 6 having a wedge shape on the outer peripheral side from the center of the rotating shaft 2 extends along the rotating shaft 2 direction. As shown in FIG. 3, each of the 17 rectangular parallelepiped permanent magnets 5 is formed in an arcuate shape, that is, in an arcuately formed parallel arrangement, and the space member 6 positions each rectangular parallelepiped permanent magnet 5. .
[0038]
Then, the hybrid permanent magnets of the 17 rectangular parallelepiped permanent magnets 5 and the 16 space members 6 arranged in parallel in an arcuate shape are fixed to the permanent magnet grooves 4 provided in the rotor laminated core 3 by fixing means such as press fitting. It is attached to the rotor laminated core 3 and constitutes the magnetic poles of the rotor 11.
[0039]
The 17 cuboid permanent magnets 5 arranged in parallel in an arcuate shape are magnetized in the form of cuboid permanent magnets 5 arranged in parallel in a bow shape in the permanent magnet grooves 4 to form magnetic poles. 5 is magnetized in a direction perpendicular to the magnetization direction of the adjacent cuboid permanent magnets 5, and the other cuboid permanent magnets 5 have the same size and the same size as shown by the arrows in FIG. 8. Now it is magnetized.
When both ends of the cuboid permanent magnet 5 constituting the magnetic pole are magnetized in a direction perpendicular to the magnetization direction of the adjacent cuboid permanent magnet 5, the magnetic path between the magnetic pole adjacent to the rotor 11 is magnetically saturated. As a result, magnetic flux leakage from the magnetic pole is reduced.
[0040]
The rotor 1 having such a configuration is used for a reluctance motor and generates a total torque T_tIs
T_t＝ k ・ φ ・ I_q+ (L_q-L_d) I_d・ I_q
It is represented by
[0041]
For example, in the rotor shown in FIG. 8, when the poles of the stator face each other between the group of one cuboid permanent magnet 5 and a similar group adjacent to each other where the cuboid permanent magnet 5 does not exist. Is referred to as the q-axis. The case where the stator poles are opposed to the center of the group of rectangular parallelepiped permanent magnets 5 (the center of the arc) is referred to as the d-axis. I above_qIs the q-axis component current (q-axis current), I_dIs the d-axis component current (d-axis current), L_qIs the inductance (q-axis inductance) generated in the stator pole coil under q-axis condition, L_dIs the inductance (d-axis inductance) generated in the stator pole coil under the d-axis state, φ is the magnetic flux generated by the group of cuboid permanent magnets 5 on the rotor, and k is the proportionality coefficient. .
[0042]
By magnetizing the magnetization directions of the cuboid permanent magnets 5 at both ends constituting each magnetic pole in a direction perpendicular to the magnetization direction of the adjacent cuboid permanent magnets 5, the d-axis leakage magnetic flux can be reduced, and the q axis Difference of inductance between L and d axis (L_q-L_d) Increases and the reluctance torque (L_q-L_d) I_d・ I_qCan be increased.
[0043]
In the first term, k · φ · I_qRepresents the torque generated by the magnet.
[0044]
FIG. 9 shows a configuration of another embodiment of the rotor used in the rotating electrical machine of the present invention. The mechanical configuration of the rotor 12 is the same as that of the rotor 1 shown in FIGS.
[0045]
As shown in FIG. 9, the plurality of rectangular parallelepiped permanent magnets 5 constituting the magnetic poles are all magnetized to the same size in the same direction, and the rotor 12 having such a configuration also has a reluctance. Used for motors.
[0046]
That is, in the configuration of (α + β) = 360 ° / M (M is an even number and the number of magnetic poles), when β> 0, the reluctance torque can be generated when the stator teeth overlap the portion of β. .
[0047]
FIG. 10 shows a configuration diagram of another embodiment of a rotor used in the rotating electrical machine of the present invention.
[0048]
  The rotor configuration of FIG. 10 is the same as the rotor configuration of FIG.β = 0This is the case.
[0049]
In the figure, the rotor 13 has a structure called a surface magnet type rotor, and 22 × 8 rectangular parallelepiped permanent magnets 5 are arranged in parallel over the entire peripheral surface of the rotor laminated core 3 to form a non-magnetic cylindrical shape. The fixing member 14 is attached to the rotor laminated core 3 by using a fixing method such as press fitting.
[0050]
In order to arrange 22 × 8 rectangular parallelepiped permanent magnets 5 arranged in parallel on the circumferential surface of the rotor laminated core 3 in a ring shape, that is, in a cylindrical shape, as shown in FIG. A non-conductive space material (not shown in FIG. 10) having a wedge shape on the outer peripheral side from the center of the rotating shaft 2 is provided along the direction of the rotating shaft 2 to position each rectangular solid permanent magnet 5. .
[0051]
In the rotor 13 shown as an example in FIG. 10, each magnetic pole having an 8-pole configuration is configured by 22 cuboid permanent magnets 5, and 22 cuboids arrayed in parallel on the circumferential surface of the rotor laminated core 3. The cuboid permanent magnet 5 of each magnetic pole composed of the permanent magnet 5 is composed of 17 cuboid permanent magnets 5 in the central portion that are the same size and magnetized in the same direction, and two cuboid permanent magnets close to both ends. 5 is gradually magnetized as it approaches both ends, and each rectangular solid permanent magnet 5-1 at the boundary between the magnetic poles is magnetized in a direction perpendicular to the magnetization direction of the adjacent rectangular solid permanent magnet 5.
[0052]
That is, the rectangular parallelepiped permanent magnets 5 at both ends constituting each magnetic pole are sequentially configured to have a large intrinsic holding force and a low residual magnetic flux density, and the rectangular parallelepiped permanent magnet 5-1 at the boundary between the magnetic poles and the magnetic pole is adjacent to the rectangular solid permanent magnet. 5 is magnetized in a direction perpendicular to the magnetizing direction.
[0053]
The rotor 13 having the cuboid permanent magnet 5 magnetized in this way has a large unilateral holding force and a large residual magnetic flux density for the cuboid permanent magnet 5 adjacent to the cuboid permanent magnet 5-1 at the boundary between the magnetic poles. Since the magnetic configuration is low, the generated magnetic flux has a magnetic flux distribution close to a sine wave, and in the motor, the magnetic center due to the armature reaction, that is, the reaction at the end of the cuboid permanent magnet 5 of the rotor 13 whose axis is shifted. It is possible to prevent partial demagnetization of the magnet with respect to the magnetic flux.
[0054]
The rotor 13 shown in FIG. 10 has the cuboid permanent magnets 5 arranged in parallel over the entire circumferential surface of the rotor laminated core 3, and the cuboid permanent magnet 5 is not arranged at the boundary between the magnetic poles. 11, the torque generated differs depending on the magnitude of the drive current flowing through the stator.
[0055]
FIG. 11 shows torque characteristic curves of the rotor 11 of FIG. 8 and the rotor 13 of FIG. 10, where (1) is the torque characteristic curve of the rotor 11 of FIG. 8, and (2) is the torque of the rotor 13 of FIG. It represents a characteristic curve.
[0056]
As can be seen from FIG. 11, when the drive current flowing through the stator winding is small, the generated torque of the rotor 13 shown in FIG. 10 is larger than that of the rotor 11 shown in FIG. When the current increases, the reluctance torque (L_q-L_d) I_d・ I_q8 is larger than the rotor 13 of FIG. 10, and when a large current flows, the rotor 11 of FIG. 8 generates a larger torque than the rotor 13 shown in FIG.
[0057]
FIG. 12 shows another parallel arrangement explanatory diagram of the rectangular parallelepiped permanent magnets constituting the magnetic poles, and the arrangement of the rectangular parallelepiped permanent magnets 5 at both ends of the rectangular parallelepiped permanent magnets 5 arranged in a bow shape in parallel with the permanent magnet grooves. By changing the angle to be larger than the angle of the other cuboid permanent magnet 5 as shown in the figure, the pulsation of the generated torque is reduced, and as a result, magnetic noise is suppressed and the motor becomes a quiet motor. Have
[0058]
  FIG. 13 shows another parallel arrangement explanatory diagram of the rectangular parallelepiped permanent magnets constituting the magnetic pole, and the rectangular parallelepiped permanent magnets 5-2 at both ends in the rectangular parallelepiped permanent magnet 5 arranged in an arcuate shape in parallel with the permanent magnet groove. Of rotating shaft 2Axis center directionEven if the length is increased, that is, deeper and longer, the leakage magnetic flux is suppressed and the pulsation of the generated torque is reduced. As a result, the magnetic noise is suppressed and the motor becomes a quiet motor as a vehicle motor. .
[0059]
The rotor 11 shown in FIG. 8, the rotor 12 shown in FIG. 9, and the rotor 13 shown in FIG. 10 are also stacked in the same manner as the rotor 1 shown in FIG. It goes without saying that may be configured.
[0060]
  FIG. 14 shows the present invention.Description of the main part structure of an embodiment of a stator used in a rotating electrical machine15 shows an exploded structural view of a part of FIG.
[0061]
14 and 15, the stator 21 includes a plurality of stacked tee scores 24 that form a stacked stator ring 22 and stator teeth 23, and a plurality of rectangular conductor wires wound around the tee score 24. And a stator coil 25.
[0062]
The stator ring 22 is provided with a number of wedge grooves 26 corresponding to the tea score 24 at equal intervals. A wedge 27 that fits into the wedge groove 26 is formed at one end of the tee score 24, and the stator teeth 23 are formed at the other end of the tee score 24.
[0063]
A stator coil 25 called a trapezoidal alignment vertically wound coil individually wound and formed as shown in FIG. 16 is inserted into a tee score 24, and a wedge 27 of the tee score 24 is press-fitted into a wedge groove 26 of the stator ring 22. Thus, the tee score 24 around which the stator coil 25 is wound is attached to the stator ring 22. Then, the stator 21 is completed by connecting the terminals of each stator coil 25 according to a predetermined connection method.
[0064]
FIG. 16 is a front view of an example winding of a stator coil, FIG. 17 is a plan view of FIG. 16, and FIG. 18 is a right side view of FIG.
[0065]
16 to 18, when the stator coil 25 called the trapezoidal alignment vertical winding coil is mounted on the tee score 24, the stator coil 25 is laminated to the base of the tee score 24, that is, toward the wedge 27. The coil is formed to have a small thickness and a wide coil width, and the cross-sectional areas of the laminated coils are formed in a constant shape.
[0066]
  Now, the number of stacked bar members (flat conductors) of the stator coil 25 is, for example, four layers, and the coil width of each layer stacked in order from the tip of the tea score 24 toward the base thereof is W.₀, W₁, W₂, W_ThreeAnd the coil thicknessT ₀ , T ₁ , T ₂ , T _Three When W₀<W₁<W₂<W_ThreeAnd T₀> T₁> T₂> T_ThreeAnd the cross-sectional areas of the stator coils 25 of each layer are equal, and W₀× T₀= W₁× T₁= W₂× T₂= W_Three× T_ThreeThe stator windings are formed so that the current density flowing in the stator coil 25 of each layer is constant.
[0067]
That is, when the stator coil 25 is attached to the stator ring 22 via the tee score 24, the trapezoidal stator coil 25 stacked in the base direction from the tip of the tee score 24 has a space factor due to its trapezoidal shape. The efficiency of the stator coil 25 and the stator ring 22 is increased and the contact area between the stator coil 25 and the stator ring 22 is increased. As a result, heat conduction to the stator ring 22 is improved. It becomes.
[0068]
FIG. 19 is an explanatory diagram of a wire shape before molding of a stator coil used in the present invention, and FIGS. 20 to 22 are explanatory diagrams of wire molding explaining a method of molding a stator coil wire used in the present invention. .
[0069]
As shown in FIGS. 19A and 19B, a thickness T of a pre-calculated dimensional length wound around the tee score 24 is shown.₀, Width W₀The bar material 30 of a uniform flat conductor is prepared, and the length L is added to the thickness of the tee score 24 plus X.₀To T₁Compressed with a wire forming die 41. Since this length L portion is compressed by the wire forming die 41, the width W₀Is W₁To spread.
[0070]
By performing the same processing at a predetermined distance of a length S obtained by adding Y to the width of the tee score 24, a thickness T is obtained as shown in FIGS.₁, Width W₁Bar material 31.
[0071]
Next, for the bar material 31 processed as described above, as in the case of FIG.₁Thickness T is further reduced at two points of the length L compressed into₁To T₂Compressed with a wire forming die 41. Since this length L portion is compressed by the wire forming die 41, the width W₁Is W₂To spread. By this step, as shown in FIGS. 21A and 21B, the thickness T₂, Width W₂Bar material 32.
[0072]
In the same manner, by repeating this process, the thickness T of the wire of the stator coil 25 as shown in FIGS. 22 (A) and 22 (B)._Three, Width W_ThreeThe bar material 33 is made.
[0073]
The bar material 33 is formed by winding using a trapezoidal winding frame whose bottom surface has a substantially cross-sectional shape with a tea score 24, whereby individual stators called trapezoidal aligned longitudinal winding coils shown in FIGS. A coil 25 is created.
[0074]
【The invention's effect】
  As explained above,According to the present invention, a rectangular parallelepipedA magnetic pole is formed by using a plurality of small permanent magnets, and the magnetic flux distribution is improved by the way of magnetization, and the leakage magnetic flux is reduced, so that a rotor that exhibits various characteristics with a simple structure can be obtained.
[0075]
  The tea score is attached to the stator ring.With the structure, it is easy to wind a flat wire with a good space factor on the stator, and the stator core is also structured so that a tee score is fitted and fixed to the stator ring. These assemblies can be assembled in a short time.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of an embodiment of a rotor used in a rotating electrical machine of the present invention.
FIG. 2 is an explanatory diagram of an embodiment of a rectangular parallelepiped permanent magnet constituting a magnetic pole.
FIG. 3 is an explanatory diagram of an arrangement of an example of a space member in which rectangular parallelepiped permanent magnets are arranged in parallel in an arcuate shape.
FIG. 4 is a magnetic flux distribution comparison diagram when the magnetic pole is a single permanent magnet and when a plurality of cuboid permanent magnets of the present invention are arranged in parallel.
FIG. 5 is an explanatory diagram of magnetization of rectangular parallelepiped permanent magnets arranged in an arcuate configuration.
FIG. 6 is an explanatory diagram of a configuration of one embodiment of a rectangular parallelepiped permanent magnet using a small permanent magnet.
FIG. 7 is an explanatory diagram of magnetization of a rectangular parallelepiped permanent magnet by a small permanent magnet.
FIG. 8 is a configuration diagram of another embodiment of a rotor used in the rotating electrical machine of the present invention.
FIG. 9 is a configuration diagram of another embodiment of a rotor used in the rotating electrical machine of the present invention.
FIG. 10 is a configuration diagram of another embodiment of a rotor used in the rotating electrical machine of the present invention.
11 is a torque characteristic curve diagram of the rotor 11 of FIG. 8 and the rotor 13 of FIG. 10;
FIG. 12 is an explanatory diagram of another parallel arrangement of cuboid permanent magnets constituting the magnetic poles.
FIG. 13 is an explanatory diagram of another parallel arrangement of rectangular parallelepiped permanent magnets constituting magnetic poles.
FIG. 14 shows the present invention.Description of the main part structure of an embodiment of a stator used in a rotating electrical machineIt is.
FIG. 15 is an exploded structural view of a part of FIG. 14;
FIG. 16 is a front view of an example winding of a stator coil.
FIG. 17 is a plan view of FIG. 16;
FIG. 18 is a right side view of FIG.
FIG. 19 is an explanatory diagram of the shape of a wire before forming a stator coil used in the present invention.
FIG. 20 is an explanatory diagram of wire forming explaining the wire forming method of the stator coil used in the present invention.
FIG. 21 is a wire forming explanatory diagram illustrating a stator coil wire forming method used in the present invention.
FIG. 22 is a wire forming explanatory diagram illustrating a stator coil wire forming method used in the present invention.
FIG. 23 is an explanatory diagram of a rotor structure of a conventional magnet-embedded reluctance motor.
[Explanation of symbols]
1 rotor
2 Rotating shaft
3 Rotor laminated core
4 Groove for permanent magnet
5 cuboid permanent magnet
6 Space material
7 Small permanent magnet
21 Stator
22 Stator ring
23 Stator Teeth
25 Stator coil
26 Wedge groove
27 Wedge

Claims (6)

A rotor having a structure including a rotating shaft, a rotor core attached to the rotating shaft, and a permanent magnet fixed to the rotor core, a stator ring, a tee score provided on the stator ring, and a stator coil wound around the tee score In a rotating electrical machine having a stator with a structure,
The rotor is
A rotor laminated core having a predetermined interval in the circumferential direction and provided with a plurality of grooves for permanent magnets along the rotation axis direction;
A plurality of rectangular parallelepiped permanent magnets arranged in parallel in the grooves for permanent magnets and constituting magnetic poles;
A non-conductive space material for positioning the cuboid permanent magnets arranged between adjacent cuboid permanent magnets for arranging a plurality of cuboid permanent magnets arranged in parallel in the grooves for permanent magnets in a bow shape; As well as
The rectangular parallelepiped permanent magnets arranged in parallel in a bow shape in the grooves for permanent magnets are magnetized in the same direction and strongly magnetized as they go from both ends to the center,
A magnetic pole composed of a plurality of rectangular parallelepiped permanent magnets arranged in the permanent magnet groove, and having a rotor in which the magnetic flux distribution on the surface of the rotor is made sinusoidal;
The stator coil of the stator is
For each tea score provided on the stator ring,
As it goes from the tip of the tea score toward its base, the thickness of each laminated coil is formed thin and the coil width is formed wide,
And the cross-sectional area of the coil of each laminated | stacked layer is formed uniformly ,
A rotating electrical machine characterized in that the winding structure of the coil is an aligned vertical winding . A rotor having a structure including a rotating shaft, a rotor core attached to the rotating shaft, and a permanent magnet fixed to the rotor core, a stator ring, a tee score provided on the stator ring, and a stator coil wound around the tee score In a rotating electrical machine having a stator with a structure,
The rotor is
A rotor laminated core having a predetermined interval in the circumferential direction and provided with a plurality of grooves for permanent magnets along the rotation axis direction;
A plurality of rectangular parallelepiped permanent magnets arranged in parallel in the grooves for permanent magnets and constituting magnetic poles;
A non-conductive space material for positioning the cuboid permanent magnets arranged between adjacent cuboid permanent magnets for arranging a plurality of cuboid permanent magnets arranged in parallel in the grooves for permanent magnets in a bow shape; As well as
Among the rectangular parallelepiped permanent magnets that are arranged in parallel in a bow shape in the permanent magnet groove and constitute the magnetic poles, the magnetization directions of the rectangular parallelepiped permanent magnets at both ends thereof are the magnetization directions of the adjacent rectangular parallelepiped permanent magnets. Magnetized in a perpendicular direction,
A rotor having reduced d-axis leakage of magnetic flux from a magnetic pole constituted by a plurality of rectangular parallelepiped permanent magnets arranged in the permanent magnet groove;
The stator coil of the stator is
For each tea score provided on the stator ring,
As it goes from the tip of the tea score toward its base, the thickness of each laminated coil is formed thin and the coil width is formed wide,
And the cross-sectional area of the coil of each laminated | stacked layer is formed uniformly ,
A rotating electrical machine characterized in that the winding structure of the coil is an aligned vertical winding . A rotor having a structure including a rotating shaft, a rotor core attached to the rotating shaft, and a permanent magnet fixed to the rotor core, a stator ring, a tee score provided on the stator ring, and a stator coil wound around the tee score In a rotating electrical machine having a stator with a structure,
The rotor is
A rotor laminated core having a predetermined interval in the circumferential direction and provided with a plurality of grooves for permanent magnets along the rotation axis direction;
A plurality of rectangular parallelepiped permanent magnets arranged in parallel in the grooves for permanent magnets and constituting magnetic poles;
A non-conductive space material for positioning the cuboid permanent magnets arranged between adjacent cuboid permanent magnets for arranging a plurality of cuboid permanent magnets arranged in parallel in the grooves for permanent magnets in a bow shape; As well as
All the rectangular parallelepiped permanent magnets arranged in parallel in a bow shape in the grooves for permanent magnets are magnetized in the same direction,
Having a rotor that generates reluctance torque due to the space between adjacent permanent magnet grooves of magnetic poles constituted by a plurality of rectangular parallelepiped permanent magnets;
The stator coil of the stator is
For each tea score provided on the stator ring,
As it goes from the tip of the tea score toward its base, the thickness of each laminated coil is formed thin and the coil width is formed wide,
And the cross-sectional area of the coil of each laminated | stacked layer is formed uniformly ,
A rotating electrical machine characterized in that the winding structure of the coil is an aligned vertical winding . A rotor having a structure including a rotating shaft, a rotor core attached to the rotating shaft, and a permanent magnet fixed to the rotor core, a stator ring, a tee score provided on the stator ring, and a stator coil wound around the tee score In a rotating electrical machine having a stator with a structure,
The rotor is
A rotor laminated core in which a plurality of rectangular parallelepiped permanent magnets are arranged in parallel on the entire circumferential surface;
A cuboid permanent magnet fixing member for fixing cuboid permanent magnets arranged in parallel on the entire circumferential surface;
A non-conductive space material for positioning the rectangular parallelepiped permanent magnets arranged between adjacent rectangular parallelepiped permanent magnets for arranging parallelepiped permanent magnets arranged in parallel on the circumferential surface of the rotor laminated core ,
A plurality of rectangular parallelepiped permanent magnets constituting magnetic poles arranged in parallel on the circumferential surface of the rotor laminated core are magnetized in the same direction in the central portion of the rectangular parallelepiped permanent magnet, and as the two ends approach, the rectangular solid permanent magnet in the central portion The rectangular parallelepiped permanent magnet is gradually magnetized in the direction of magnetization of the magnetic pole and becomes a boundary between the magnetic poles, and is magnetized in a direction perpendicular to the magnetization direction of the adjacent rectangular solid permanent magnet,
A magnetic pole composed of a plurality of rectangular parallelepiped permanent magnets having a rotor whose magnetic flux distribution on the surface of the rotor is made sinusoidal,
The stator coil of the stator is
For each tea score provided on the stator ring,
As it goes from the tip of the tea score toward its base, the thickness of each laminated coil is formed thin and the coil width is formed wide,
And the cross-sectional area of the coil of each laminated | stacked layer is formed uniformly ,
A rotating electrical machine characterized in that the winding structure of the coil is an aligned vertical winding .   5. The rotating electrical machine according to claim 1, wherein the rectangular parallelepiped permanent magnet includes a plurality of small permanent magnets stacked in a rotation axis direction and a radial direction thereof.   The stator ring is provided with a plurality of fitting grooves at equal intervals on the inner peripheral surface thereof, and the teascore has a stator tooth formed on one side thereof and a fitting provided on the inner peripheral surface of the stator ring on the other side. 5. A stator core is formed by forming a fitting portion to be engaged with the groove, and the fitting portion of the tee score is fitted into the fitting groove of the stator ring. The rotating electrical machine according to Crab.

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