JP3695344B2 - Rotating electric machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a rotating electrical machine.
[0002]
[Prior art]
As a permanent magnet motor in which a permanent magnet is embedded in a rotor, JP-A-5-300712 discloses that a permanent magnet is moved in the axial direction according to the rotational speed of the motor so as to suppress back electromotive force during high-speed rotation. However, in Japanese Patent Application Laid-Open No. 11-206046, the permanent magnet is either obliquely magnetized or the magnetized permanent magnet is preliminarily arranged to change the phase difference between the magnet torque and the reluctance torque, thereby increasing the torque. What has been improved is disclosed.
[0003]
[Problems to be solved by the invention]
By the way, in the technique of Japanese Patent Laid-Open No. 5-300712, the permanent magnet is moved in the axial direction by a weight that can be moved in the radial direction by using centrifugal force. Depending on factors other than the rotational speed, the axial direction of the permanent magnet The amount of movement cannot be controlled. Also, the angle of the permanent magnet with respect to the stator cannot be changed. In other words, depending on the technique disclosed in Japanese Patent Laid-Open No. 5-300712, it is impossible to arbitrarily change the magnetic field strength and magnetic field direction of the permanent magnet with respect to the stator in accordance with an instruction from the outside.
[0004]
This situation is the same in the technique disclosed in Japanese Patent Application Laid-Open No. 11-206046. That is, it is difficult to change the magnetization direction again after magnetization, and the angle of the permanent magnet with respect to the stator cannot be changed after the permanent magnet is installed obliquely.
[0005]
Therefore, an object of the present invention is to provide a rotating electrical machine that can easily control the magnetic field strength and magnetic field direction of a permanent magnet by an external instruction.
[0008]
[Means for Solving the Problems]
  First1DepartureTomorrow,A rotating electric machine comprising a stator and a rotor including a permanent magnet, a magnetic field strength control means capable of controlling the magnetic field strength of the permanent magnet with respect to the stator according to the rotational speed of the rotor, and the rotational speed of the rotor And a magnetic field direction control means capable of controlling the magnetic field direction of the permanent magnet relative to the stator,The magnetic field intensity control means controls the distance of the permanent magnet to the stator.
[0009]
  First2DepartureTomorrow,A rotating electric machine comprising a stator and a rotor including a permanent magnet, a magnetic field strength control means capable of controlling the magnetic field strength of the permanent magnet with respect to the stator according to the rotational speed of the rotor, and the rotational speed of the rotor And a magnetic field direction control means capable of controlling the magnetic field direction of the permanent magnet relative to the stator,The magnetic field direction control means controls the tilt angle of the permanent magnet with respect to the stator.
[0010]
  First3DepartureTomorrow,A rotating electrical machine comprising a stator and a rotor including a permanent magnet, the magnetic field strength control means capable of controlling the magnetic field strength of the permanent magnet with respect to the stator according to the rotational speed of the rotor, and the rotational speed of the rotor And a magnetic field direction control means capable of controlling the magnetic field direction of the permanent magnet relative to the stator,A rotor magnet section (see FIG. 22) that is rotatable around an axis and is provided with a permanent magnet at a position offset from the axis is provided. The magnetic field intensity control means and the magnetic field direction control means control the magnetic field direction of the permanent magnet. It is possible magnetic field direction control means.
[0011]
  First4DepartureTomorrow,A rotating electrical machine comprising a stator and a rotor including a permanent magnet, the magnetic field strength control means capable of controlling the magnetic field strength of the permanent magnet with respect to the stator according to the rotational speed of the rotor, and the rotational speed of the rotor And a magnetic field direction control means capable of controlling the magnetic field direction of the permanent magnet relative to the stator,The rotor rotates around the axis of the rotor base, a rotor magnet part that is rotatable around the axis and is provided with a permanent magnet at a position offset from the axis, and the rotor magnet part revolves around the axis of the rotor base. And a pair of rotation support members that are disposed before and after the rotor base so as to be able to rotate and support the rotor base and the rotor magnet, and the magnetic field intensity control means and the magnetic field direction control means are configured to rotate with the revolution center of the rotor magnet. The tilt angle control means can control the tilt angle in the magnetic field direction of the permanent magnet with respect to the line connecting the center.
[0012]
Here, the pair of rotation support members may be can-shaped rotation support members 41 and 45 as shown in FIGS. 1, 7, 8, and 9, or FIGS. As shown in FIG. 18, disk-shaped rotation support members 51 and 55 may be used.
[0013]
  First5In the invention of the3In this invention, the magnetic field direction control means tilts the magnetic field direction of the permanent magnet as the rotational speed of the rotor increases.
[0014]
  First6In the invention of the4In the present invention, the tilt angle control means increases the tilt angle of the permanent magnet in the magnetic field direction as the rotational speed of the rotor increases.
[0015]
  First7In the invention of the4Or second6In this invention, the tilt angle control means includes a gear mechanism that is supported by one of the rotation support members and allows the rotor magnet portion to rotate, an actuator that operates the gear mechanism, and a clutch that connects and disconnects the power transmission of the actuator to the gear mechanism. It consists of.
[0016]
In this case, the gear mechanism may be at least two gears 111 and 112 that mesh as shown in FIGS. 1, 7, 8, and 9. The actuators are, for example, sub motors 120 and 124 as shown in FIGS.
[0017]
  First8In the invention of the7In this invention, the actuator is a motor composed of a rotor and a stator.
[0018]
  First9In the invention of the4Or second6In the present invention, the tilt angle control means includes a gear mechanism that is supported by one of the rotation support members and allows the rotor magnet portion to rotate, a compound planetary gear that operates the gear mechanism, and a lever that gives a command to the compound planetary gear It consists of.
[0019]
In this case, the gear mechanism may be at least two gears 111 and 112 that mesh with each other as shown in FIGS. 10, 13, 17, and 18.
[0020]
  First10In the invention of the9In this invention, the gear mechanism is configured to include a first gear that can rotate integrally with the rotor magnet portion, and the compound planetary gear includes two or more planetary gears including a sun gear, a ring gear, a pinion, and a carrier. The following conditions apply to compound planetary gears
  Condition 1: One of the sun gear, ring gear, and carrier is selected, and one of the selected pair of parts is indirect or direct meshing with the first gear, and the other is directly or indirectly coupled with the support member. Doing things,
  Condition 2: One of the remaining two parts selected in condition 1 is selected, and one of the selected pair of parts is coupled to the case and the other is coupled to the lever.
  Condition 3: A pair of parts not selected in Condition 2 are connected to each other.
It is a connection pattern that satisfies all of the above.
[0021]
【The invention's effect】
FirstThe second2According to the invention, the magnetic field strength (the number of magnetic fluxes linked to the stator) and the magnetic field direction with respect to the stator can be arbitrarily controlled according to instructions from the outside, for example, operating conditions and rotor rotational speed. The characteristics of the rotating electrical machine can be greatly improved.
[0022]
  First3The second4The second7~10According to the invention, since the magnetic field direction of the permanent magnet can be changed independently of the rotation of the rotor, an arbitrary magnetic field can be created.
[0023]
  In general, so-called field weakening control is performed in a region where the rotational speed of the rotor (motor rotational speed) is high in order to suppress the induced voltage. With this control, when the induced voltage in the high rotation speed range is larger than the maximum voltage that can be output by the inverter, the magnet torque is hardly output, and the total torque of the motor is mainly reluctance torque. On the other hand, when the induced voltage in the high rotational speed region is smaller than the maximum voltage that can be output by the inverter, the magnet torque can be used. Therefore, when the permanent magnet is tilted as the motor rotation speed increases, the induced voltage is less than when the permanent magnet tilt is restricted (that is, in the case of a general motor in which the permanent magnet is fixed to the rotor). The total torque of the motor is increased by this magnet torque while effectively suppressing the increase and using the magnet torque effectively. I.e.5The second6According to the invention, by tilting the permanent magnet according to the motor rotation speed, the total torque of the motor can be improved while suppressing the induced voltage as compared with the case of the motor that cannot tilt the permanent magnet. Can do.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a first embodiment of the present invention will be described with reference to the accompanying drawings.
[0025]
1 is a cross-sectional view of the motor in the axial direction, and FIG. 2 is a plan view of the rotor portion taken along the line AA of FIG. Although FIG. 1 shows the bearings with different sizes, there is no special meaning.
[0026]
The motor includes a motor case 1, a stator 2, a rotor 3, and an output shaft 4 for extracting the rotational force of the rotor 3. The rotor 3 further includes a disk-shaped rotor base portion 20, a rotor shaft 21, and a rotor magnet portion 30.
[0027]
The rotor magnet portion 30 is formed in a long cylindrical shape as a whole. The four rotor magnet portions 30 have the same configuration, and as shown in FIG. 2, the permanent magnet 31 is offset (disengaged) from the shaft 33 of the rotor magnet portion 30 and substantially in the diametrical direction. It is embedded in a right angle. Then, as shown in FIG. 2, the outer edge of the rotor magnet part 30 is arranged at equal intervals in the circumferential direction of the rotor base 20 so that it slightly protrudes from the outer periphery of the rotor base 20.
[0028]
The rotor magnet 30 further rotates around the rotor shaft 21 while being revolved, so that the rotor support 30 can rotate around the rotor base 20 (the left side is the front and the right side is the rear in FIG. 1). Is provided. The rotation support mechanism 40 includes a can-like rotation support member 41 arranged in front of the rotor 3 and a can-like rotation support member 45 arranged behind the rotor 3.
[0029]
First, the rotor base 20 is rotatably supported as follows. That is, the rotor shaft 21 protruding forward is coupled to the output shaft 4 via the front rotation support member 41, and is thus supported by the bearing 5 provided on the front wall 1 a of the motor case 1. On the other hand, the rotor shaft 21 protruding rearward is supported by a bearing 46 provided on the front wall 45 a of the rear rotation support member 45. The output shaft 4 and the rotor shaft 21 may be composed of the same member as shown in FIG.
[0030]
Next, the rotor magnet unit 30 is supported as follows. That is, the rotor magnet portion 30 has a shaft 42 protruding forward and a bearing 42 provided near the outer periphery of the rear wall 41a of the front rotation support member 41, and a shaft 33 protruding rearward is the front wall of the rear rotation support member 45. It is supported by a bearing 47 provided near the outer periphery of 45a.
[0031]
By configuring the front rotation support member 41 and the rear rotation support member 45 in this way, the rotor magnet portion 30 rotates around the shaft 33 of the rotor magnet portion 30 while revolving around the rotor shaft 21. It becomes possible. Since the permanent magnet 31 is provided at a position eccentric with respect to the shaft 33, the inclination of the permanent magnet 31 changes when the rotor magnet unit 30 rotates. Here, the “tilt angle” of the permanent magnet 31 is defined as follows. When represented by one rotor magnet portion 30 located on the right in FIG. 2, the permanent magnet 31 is formed so that the magnetic field direction is the left-right direction in the figure. At this time, the revolution center (rotor shaft) of the rotor magnet portion 30 is formed. 21) and the direction of the straight line connecting the rotation center (core of the shaft 33) and the magnetic field direction of the permanent magnet 31 coincide. The angle at which the permanent magnet 31 tilts when this position (state of FIG. 2) is set as the reference position and the rotor magnet 30 is rotated counterclockwise in the drawing from the reference position assuming that the rotor 3 rotates clockwise in the drawing. Is defined as the tilt angle. That is, the angle at which the magnetic field direction of the permanent magnet 31 is tilted about the axis 33 is the tilt angle. When the permanent magnet 31 is in the state shown in FIG. 2, the tilt angle of the permanent magnet 31 is 0 degree. The tilt angle of the permanent magnet 31 increases as the rotor magnet portion 30 rotates counterclockwise.
[0032]
The motor includes a mechanism 100 (hereinafter referred to as “tilt angle control mechanism”) that controls the tilt angle of the permanent magnet 31. The tilt angle control mechanism 100 (tilt angle control means) includes a can-shaped rotation support member 115 that rotates inside the rotor shaft 21 in the rear rotation support member 45 and the inner rotation support member 115. The first gear 111 and the second gear 112, the sub motor 120, and the clutch 130 are housed.
[0033]
Specifically, the first gear 111 that can rotate integrally with the rotor magnet unit 30 has the front wall 115a and the rear wall of the inner rotation support member 115 such that the axis thereof is at the same axial position as the shaft 33 of the rotor magnet unit 30. It is supported by bearings 116 and 117 provided near the outer periphery of 115b. The second gear shaft 113 is supported by a bearing 118 provided on the rear wall 115b of the inner rotation support member 115 and a bearing 48 provided on the outer rotation support member 45 so as to be in the same position as the rotor shaft 21 and the axis. ing. The bearing 48 also serves as a bearing that supports the outer rotation support member 45.
[0034]
The sub motor 120 fixed to the rear outer side of the motor case 1 and coupled to the second gear shaft 113 includes a sub case 124, a sub stator 121, a sub rotor 122, a rotating shaft 123, and bearings 125 and 126. The rotating shaft 123 is a second gear shaft. 113 is integrally coupled.
[0035]
The clutch 130 provided inside the rotation support member 45 located outside and behind the rotation support member 115 located inside is constituted by, for example, a wet friction multi-plate clutch. That is, it is composed of one member (for example, a clutch disk) 130a fixed to the second gear shaft 113 and the other member (for example, a pressure plate) 130b fixed to the rear wall 115b of the inner rotation support member 115. Then, the second gear shaft 113 and the inner rotation support member 115 are connected or disconnected. The connection state between the second gear shaft 113 and the inner rotation support member 115 is the engagement state of the clutch 130, and the connection state between the second gear shaft 113 and the inner rotation support member 115 is the release state of the clutch 130.
[0036]
Here, the operation of the present embodiment will be described.
[0037]
For simplicity, the case where the motor (rotor base 20) is stopped will be described first. When the clutch 130 is engaged, the second gear 112 is fixed with respect to the inner rotation support member 115 and cannot rotate even if the rotation shaft 123 is to be rotated. For this reason, the first gear 111 meshing with the second gear 112 cannot rotate.
[0038]
On the other hand, when the clutch 130 is released, the second gear 112 rotates by the same angle as the rotation angle of the rotary shaft 123, and the first gear 111 rotates by a predetermined angle accordingly. In this case, the predetermined angle is determined according to the rotation angle of the second gear 112 and the gear ratio of the two gears 111 and 112.
[0039]
Here, the rotation angle of the first gear 111 is equal to the rotation angle of the rotor magnet unit 30, and the rotation angle of the second gear 112 is equal to the rotation angle of the rotation shaft 123. The rotation angle of the rotor magnet unit 30 changes. That is, the tilt angle of the permanent magnet 31 can be arbitrarily controlled by the sub motor 120.
[0040]
Next, the case where the motor is operating (the rotor base 20 is rotating) will be described. When the clutch 130 is engaged, the rotation of the rotor base 20 is transmitted to the outer rotation support member 45 and the inner rotation support member 115 through the coupling of the rotor magnet unit 30 and the first gear 111, and the inner rotation support member 115. The rotation is further transmitted to the rotation shaft 123 via the clutch 130, so that the rotation support members 45 and 115, the clutch 130, and the rotation shaft 123 rotate together at the same rotational speed as the rotor base 20.
[0041]
When the clutch 130 is released in this state and the rotational speed of the rotating shaft 123 (rotational speed of the sub motor 120) is controlled so that a rotational speed difference is generated with respect to the rotational speed of the rotor base 20 (motor rotational speed), the rotational speed is increased. The rotor magnet portion 30 rotates according to the difference, and thereby the permanent magnet 31 tilts.
[0042]
Thus, it can be seen that the tilt angle of the permanent magnet 31 can be arbitrarily controlled by the combination of the rotational speed control of the sub motor 120 in the tilt angle control mechanism 100 and the engagement / release of the clutch 130.
[0043]
Next, the relationship between the tilt angle of the permanent magnet 31 and the motor rotation speed and the influence of the tilt angle of the permanent magnet 31 on the induced voltage and the total torque (magnet torque + reluctance torque) of the motor will be described.
[0044]
As described above, the tilt angle of the permanent magnet 31 is the reference position when the direction of the magnetic field of the permanent magnet 31 coincides with the direction of the straight line connecting the revolution center and the rotation center of the rotor magnet portion 30 (state shown in FIG. 2). As a tilted angle of the permanent magnet 31 from the reference position. That is, the angle at which the magnetic field direction of the permanent magnet 31 is tilted about the axis 33 of the rotor magnet unit 30 is defined as the tilt angle.
[0045]
FIG. 3 shows the characteristics of the tilt angle with respect to the motor rotation speed. As shown in the figure, the tilt angle is set to increase as the motor rotation speed increases. In the figure, the maximum tilt angle is shown as 90 degrees, for example.
[0046]
FIG. 4 shows the characteristics of the induced voltage of the motor with respect to the tilt angle when the motor rotation speed is the same. As shown in the figure, the induced voltage of the motor decreases as the tilt angle increases. This is because the distance between the permanent magnet 31 and the stator 2 increases as the permanent magnet 31 tilts from the reference position, the magnetic field strength decreases, and the induced voltage decreases correspondingly.
[0047]
FIGS. 5 and 6 are characteristics showing how the total torque of the motor is affected by the difference in tilt angle when the motor rotation speed is the same. The total torque of the motor is increased when the tilt angle shown in FIG. 6 is 20 degrees than when the tilt angle shown in FIG. 5 is 0 degrees. As shown in FIG. 6, when the permanent magnet 31 tilts, the direction of the magnetic field generated by the permanent magnet 31 with respect to the stator 2 changes, so that the phase of the magnet torque changes with respect to the current, and the maximum value of the magnet torque becomes reluctance. This is because it approaches the maximum value of the torque, which increases the total torque.
[0048]
In general, in a region where the motor rotation speed is high, so-called field weakening control is performed in order to suppress the induced voltage. With this control, when the induced voltage in the high rotation speed range is larger than the maximum voltage that can be output by the inverter, the magnet torque is hardly output, and the total torque of the motor is mainly reluctance torque. On the other hand, when the induced voltage in the high rotational speed region is smaller than the maximum voltage that can be output by the inverter, the magnet torque can be used. Therefore, when the permanent magnet 31 is tilted as the motor rotational speed becomes higher, the induced voltage is compared with the case where the tilting of the permanent magnet is restricted (that is, in the case of a general motor in which the permanent magnet is fixed to the rotor). The total torque of the motor is increased by the magnet torque while effectively using the magnet torque while suppressing the increase of the motor. That is, by tilting the permanent magnet 31 according to the motor rotation speed, the total torque of the motor can be improved while suppressing the induced voltage as compared with a motor that cannot tilt the permanent magnet.
[0049]
7, 8, and 9 are axial sectional views of the motors of the second, third, and fourth embodiments. Note that the same parts as those in FIG.
[0050]
First, the second and third embodiments are different from the first embodiment in that the sub motor is arranged inside the motor case 1. That is, in FIG. 7 of the second embodiment, the sub-stator 121 of the sub-motor 120 is fixed to the constituent member 130b of the clutch 130, and the sub-rotor 122 is arranged with a predetermined gap from the sub-stator 121.
[0051]
In FIG. 8 of the third embodiment, the sub-stator 128 of the sub-motor 127 is fixed to the front wall 1a of the motor case 1, and the sub-rotor 129 is placed on the outer periphery of the front rotation support member 41 with a predetermined gap from the sub-stator 128. Has been placed. In this case, the motor (rotor base 20) and the sub motor (sub rotor 129) rotate at the same rotational speed when the clutch 130 is engaged, and the sub motor is controlled so that a rotational speed difference is generated between them when the clutch 130 is released. The rotor magnet unit 30 rotates.
[0052]
Next, the fourth embodiment shown in FIG. 9 is different from the first embodiment in that the sub motor is eliminated. Next, it will be described that the tilt angle of the permanent magnet 31 can be controlled even if the sub motor is eliminated.
[0053]
If the clutch 130 is engaged when the motor is rotating, the rotor magnet unit 30 cannot rotate. At this time, all the force that the rotor magnet unit 30 receives from the stator 2 is used for the revolution of the rotor magnet unit 30, that is, the rotation of the output shaft 4. On the other hand, when the clutch 130 is released, a part of the force that the rotor magnet unit 30 receives from the stator 2 is used for the rotation of the rotor magnet unit 30. Therefore, it is possible to arbitrarily control the rotation angle of the rotor magnet unit 30 (the tilt angle of the permanent magnet 31) by controlling the release time of the clutch 130.
[0054]
When the rotation angle of the rotor magnet unit 30 is controlled, the rotor magnet unit 30 rotates in a direction in which the motor torque is removed. For example, when the tilt angle of the permanent magnet 31 is to be controlled to 20 degrees, the rotor magnet unit 30 As shown in FIG. 24, 30 is rotated clockwise by 340 degrees in the figure.
[0055]
According to the second and third embodiments, the sub motors 120 and 127 are provided in the motor case 1, and according to the fourth embodiment, the sub motor is omitted. The configuration of the motor is more compact than in the embodiment.
[0056]
Next, FIG. 10 is a sectional view in the axial direction of the motor of the fifth embodiment, and FIG. 11 is a layout view of the first and second gears 111 and 114 seen in the section taken along line BB in FIG. In FIG. 10, the same parts as those in FIG.
[0057]
In the fifth embodiment, instead of the clutch 130 and the sub motor 120 shown in FIG. 1, a compound planetary gear in which two planetary gears 140 and 150 are combined in the front-rear direction (the left side is the front and the right side is the rear in FIG. 10) is used. It was. Therefore, in the fifth embodiment, the tilt angle control mechanism 104 is composed of the compound planetary gear, the first gear 111, the second gear 112, and the lever 160.
[0058]
In FIG. 10, unlike FIG. 1, the output shaft 4 is configured to penetrate the front wall 1 a and the rear wall of the motor case 1, and is a can-like rotation support member disposed before and after the rotor 3 shown in FIG. 1. Instead of 41 and 45, disc-shaped rotation support members 51 and 55 are used. Therefore, in the fifth embodiment, the first gear 111 and the second gear 112 are arranged further rearward of the rear disk-shaped rotation support member 55.
[0059]
The composite planetary gear will be described. Among the first planetary gears 140 including the sun gear 141, the first pinion 142, the first ring gear 143, and the first carrier 144, the first carrier 144 is the second gear 112, and A first ring gear 143 is coupled to the motor case 1, and a second rear planetary gear 150, which includes a sun gear 141 (shared with the first planetary gear 140), a second pinion 152, a second ring gear 153, and a second carrier 154. Of these, the second carrier 154 is integrated with the output shaft 4, and the second ring gear 153 is coupled with the lever 160.
[0060]
When the motor is operating with the lever 160 (second ring gear 153) held (the output shaft 4 is rotating), the second carrier 154 rotates at the same speed as the output shaft 4, and the second carrier 154 rotates accordingly. While the two-pinion 152 revolves along the second ring gear 153, it also rotates. Due to the rotation of the second ring gear 153, the sun gear 141 rotates at a predetermined speed. On the other hand, since the first ring gear 143 is fixed to the motor case 1, when the sun gear 141 rotates at a predetermined speed, the first pinion 142 itself rotates while revolving along the first ring gear 143. At this time, the revolution speeds of the first pinion 142 and the second pinion 152 are the same, and the first carrier 144 and the second carrier 154 rotate at the same speed.
[0061]
When the lever 160 is moved from this state and the second ring gear 153 is rotated by a predetermined angle relative to the circumferential direction of the motor, the first carrier 144 is moved relative to the second carrier 154 by an angle corresponding to the amount of movement of the lever 160. The second gear 112 is rotated by the same angle as the angle at which the first carrier 144 is relatively rotated. Due to the rotation of the second gear 112 at this predetermined angle, the first gear 111 rotates at an angle corresponding to the gear ratio of both gears, whereby the rotor magnet unit 30 rotates by the same angle as the rotation angle of the first gear 111.
[0062]
Thus, when the lever 160 is moved by a predetermined amount relative to the motor case 1, the rotor magnet portion 30 can rotate by an angle corresponding to the amount of movement of the lever 160 as shown in FIG. Yes, the fifth embodiment can provide the same effects as the first embodiment.
[0063]
The upper end 161 of the lever 160 is extended until it protrudes outside the motor case 1, and the upper end 161 is configured to be movable in the circumferential direction of the motor by a step motor (actuator) (not shown). However, the actuator is not limited to this.
[0064]
FIG. 13 is a sectional view in the axial direction of the motor of the sixth embodiment, and FIG. 14 is a plan view of the rotor 3.
[0065]
As compared with the fifth embodiment, the sixth embodiment is provided with the same number of rotor magnet portions 34 as the rotor magnet portions 30 as shown in FIG. 4 and 4 are arranged on the periphery of the rotor base 20 as a pair. In this case, the configuration of the rotor magnet unit 30 is the same as that of the fifth embodiment. On the other hand, the rotor magnet portion 34 has its shaft 37 integrally coupled to the third gear 165 as shown in FIG. 13, and the third gear 115 meshes only with the first gear 111 as shown in FIG. It has become. In order to clarify the configuration of the newly added rotor magnet portion 34 and the third gear 165, FIG. 13 shows a cross section taken along line C-D-E in FIGS.
[0066]
When the tilt angle control mechanism 105 is configured by adding the third gear 115 to the first gear 111, the second gear 112, the compound planetary gear, and the lever 160 as described above, the lever 160 is also connected to the motor case 1 in the sixth embodiment. As shown in FIG. 16, the rotor magnet portion 30 rotates by an angle corresponding to the amount of lever movement. This is the same as in the fifth embodiment.
[0067]
On the other hand, when the rotor magnet portion 30 rotates by a predetermined angle, the rotor magnet portion 34 is opposite to the rotor magnet portion 30 by an angle determined by the gear ratio of the first gear 111 and the third gear 165 and the rotation angle of the first gear. Rotate in the direction. At this time, as shown in FIG. 16, as the amount of lever movement increases, the number of magnetic fluxes linked to the stator 2 increases, that is, the magnetic field strength with respect to the stator 2 increases.
[0068]
17 and 18 are axial sectional views of the motors of the seventh and eighth embodiments, which replace FIG. 10 of the fifth embodiment. However, the lower half of the output shaft 4 is not shown.
[0069]
These two embodiments show other uses (variations) of the compound planetary gear. That is, in the case of FIG. 17, among the first planetary gears 170 including the first sun gear 171, the first pinion 172, the ring gear 173, and the first carrier 174, the first sun gear 171 is the second gear 112, The first carrier 174 is coupled to the motor case 1, and the second planetary gear behind the second sun gear 181, the second pinion 182, the ring gear 173 (shared with the first planetary gear 170), and the second carrier 184. Of the 180, the second sun gear 181 is coupled to the output shaft 4, and the second carrier 184 is coupled to the lever 162. The two planetary gears 170 and 180, the first gear 111, the second gear 112, and the lever 162 constitute the tilt angle control mechanism 106.
[0070]
On the other hand, in the case of FIG. 18, the first planetary gear 190 in front including the first sun gear 191, the first pinion 192, the first ring gear 193, and the first carrier 194 (integrated with the second carrier 204 of the second planetary gear 200). Of these, the first sun gear 191 is coupled to the second gear 114, and the first ring gear 193 is coupled to the motor case 1, whereas the second sun gear 201, the second pinion 202, the second ring gear 203, and the second carrier 204 are coupled thereto. The second sun gear 201 is coupled to the output shaft 4, and the second ring gear 203 is coupled to the lever 163. The two planetary gears 190 and 200, the first gear 111, the second gear 112, and the lever 163 constitute the tilt angle control mechanism 107.
[0071]
Since the seventh and eighth embodiments are different from the fifth embodiment only in the way of connecting the compound planetary gears, the operational effects obtained by the seventh and eighth embodiments are the same as those of the fifth embodiment. .
[0072]
In the fifth, seventh, and eighth embodiments, three different connection methods (connection patterns) in the case of using a compound planetary gear have been shown, but there are actually six connection patterns in total including these three connection patterns. In summary, it is as shown in FIG. For example, taking the fifth embodiment as an example, in the fifth embodiment, a pair of carriers, a pair of ring gears, and a pair of sun gears of a compound planetary gear are connected as follows.
[0073]
Carrier: One (first carrier 144) is indirectly meshed with the first gear 111, and the other (second carrier 154) is directly coupled to the output shaft 4 as a support member.
[0074]
Ring gear: One (first ring gear 143) is coupled to the case 1, and the other (second ring gear 153) is coupled to the lever 160.
[0075]
Sun gear: The sun gear 141 is shared and is therefore coupled to each other.
[0076]
When such a connection pattern of the fifth embodiment is applied to FIG. 19, it is understood that this corresponds to the case of “connection pattern 1” at the right end. Similarly, the seventh and eighth embodiments shown in FIGS. 17 and 18 correspond to “connection pattern 5” and “connection pattern 6”. Accordingly, the connection patterns 2, 3, and 4 shown in FIG. 19 are the other three embodiments (the ninth, tenth, and eleventh embodiments) although not shown.
[0077]
Variations of the rotor 3 are shown in FIGS. That is, FIG. 20 (the twelfth embodiment) has the permanent magnets 38 embedded in the rotor base 20, and FIG. 21 (the thirteenth embodiment) has the number of rotor magnet portions 30 doubled to eight.
[0078]
FIG. 22 (fourteenth embodiment) shows the rotor magnet portion 30 that protrudes completely outside the rotor base portion 24.
[0079]
Here, when the axial sectional view of the motor corresponding to FIG. 1 is shown in FIG. 23, in the fourteenth embodiment, the rotor shaft 21 that protrudes to the outside of the case 1 forward is provided on the front wall 1 a of the case 1. Is supported by
[0080]
On the other hand, the rotor shaft 21 protruding rearward passes through the front wall 115a of the can-like rotation support member 115 and is coupled to the second gear 112. In this case, since the second gear shaft 113 is rotationally supported by the bearing 125, the rotor shaft 21 protruding rearward is supported by the bearing 125 together with the second gear 112. The rotation support member 115 is rotatably supported with respect to the rotor shaft 21 via the bearing 201.
[0081]
The shaft 33 of the rotor magnet unit 30 is rotationally supported by a bearing 42 provided on the rear wall peripheral portion of the rotation support member 204 positioned in front of the rotor base 24 in front. Although this point is the same as that of 1st Embodiment, the structure of the rotation support member 204 differs from 1st Embodiment. That is, the rotation support member 204 includes a cylindrical small-diameter portion 204a and a large-diameter portion 204b. Of these, the small-diameter portion 204a is provided by the bearing 205 provided on the case front wall 1a, and the large-diameter portion 204b is provided on the rear wall 204c. The rotor 206 is rotatably supported by a bearing 206 provided on the rotor shaft 21.
[0082]
If comprised in this way, the revolution speed of the rotor magnet part 30 and the rotational speed of the rotor base part 24 will become the same with the clutch 130 being a fastening state, and the sub motor 120 is operated with respect to this with the clutch 130 released. As a result, a relative speed difference is generated between the revolution speed of the rotor magnet portion 30 and the rotation speed of the rotor base portion 24, whereby the rotor magnet portion 30 can rotate. Such an action is the same as in the first embodiment.
[0083]
However, unlike the first embodiment, according to the fourteenth embodiment of FIG. 23, either the rotor shaft 21 or the rotation support member 204 (small diameter portion 204a) can be used as the motor output shaft.
[0084]
In the embodiment, the case where the tilt angle of the permanent magnet is controlled according to the motor rotation speed is described, but the present invention is not limited to the motor rotation speed, and other operation condition signals can be used.
[Brief description of the drawings]
FIG. 1 is an axial sectional view of a motor.
FIG. 2 is a plan view of a rotor portion taken along line AA in FIG.
FIG. 3 is a characteristic diagram of a tilt angle with respect to a motor rotation speed.
FIG. 4 is a characteristic diagram of an induced voltage with respect to a tilt angle.
FIG. 5 is a waveform diagram showing a change in total torque when the tilt angle is 0 degree.
FIG. 6 is a waveform diagram showing a change in total torque when the tilt angle is 20 degrees.
FIG. 7 is an axial sectional view of a motor according to a second embodiment.
FIG. 8 is an axial sectional view of a motor according to a third embodiment.
FIG. 9 is an axial sectional view of a motor according to a fourth embodiment.
FIG. 10 is an axial sectional view of a motor according to a fifth embodiment.
FIG. 11 is a layout view of first and second gears of a fifth embodiment.
FIG. 12 is a characteristic diagram showing the relationship between the lever movement amount and the tilt angle according to the fifth embodiment.
FIG. 13 is an axial sectional view of a motor according to a sixth embodiment.
FIG. 14 is a plan view of a rotor unit according to a sixth embodiment.
FIG. 15 is a layout view of first, second, and third gears of a sixth embodiment.
FIG. 16 is a characteristic diagram showing the relationship between the lever movement amount and the tilt angle according to the sixth embodiment.
FIG. 17 is an axial sectional view of a motor according to a seventh embodiment.
FIG. 18 is an axial sectional view of a motor according to an eighth embodiment.
FIG. 19 is a table showing a connection pattern of compound planetary gears.
FIG. 20 is a plan view of a rotor according to a twelfth embodiment.
FIG. 21 is a plan view of a rotor according to a thirteenth embodiment.
FIG. 22 is a plan view of a rotor according to a fourteenth embodiment.
FIG. 23 is an axial sectional view of a motor according to a fourteenth embodiment.
FIG. 24 is a plan view of a rotor for explaining the operation of the fourth embodiment.
[Explanation of symbols]
2 Stator
3 Rotor
4 Output shaft
20 Rotor base
30 Rotor magnet
31 Permanent magnet
34 Rotor magnet
40 Rotating support member
41 Forward rotation support member
45 Back rotation support member
100 Tilt angle control mechanism (Tilt angle control means)
101 Tilt angle control mechanism (Tilt angle control means)
102 Tilt angle control mechanism (Tilt angle control means)
103 Tilt angle control mechanism (Tilt angle control means)
104 Tilt angle control mechanism (Tilt angle control means)
105 Tilt angle control mechanism (Tilt angle control means)
106 Tilt angle control mechanism (Tilt angle control means)
107 Tilt angle control mechanism (Tilt angle control means)
111 1st gear
112 Second gear
120 Sub motor
130 Clutch
140 First planetary gear
150 Second planetary gear
165 Third gear
170 First planetary gear
180 Second planetary gear
190 First planetary gear
200 Second planetary gear

Claims (10)

A rotating electric machine comprising a stator and a rotor including a permanent magnet, a magnetic field strength control means capable of controlling the magnetic field strength of the permanent magnet with respect to the stator according to the rotational speed of the rotor, and the rotational speed of the rotor And a magnetic field direction control means capable of controlling the magnetic field direction of the permanent magnet relative to the stator,
Rotary electric machine you wherein magnetic field intensity control means for controlling the distance of the permanent magnet relative to the stator. A rotating electric machine comprising a stator and a rotor including a permanent magnet, a magnetic field strength control means capable of controlling the magnetic field strength of the permanent magnet with respect to the stator according to the rotational speed of the rotor, and the rotational speed of the rotor And a magnetic field direction control means capable of controlling the magnetic field direction of the permanent magnet relative to the stator,
Rotary electric machine you wherein the magnetic field direction control means for controlling the inclination angle of the permanent magnet relative to the stator. A rotating electric machine comprising a stator and a rotor including a permanent magnet, a magnetic field strength control means capable of controlling the magnetic field strength of the permanent magnet with respect to the stator according to the rotational speed of the rotor, and the rotational speed of the rotor A magnetic field direction control means capable of controlling the magnetic field direction of the permanent magnet with respect to the stator , and a rotor magnet portion that is rotatable about an axis and provided with a permanent magnet at a position offset from the axis,
Magnetic field intensity controlling unit and the magnetic field direction control unit, rotating electric machine you being a magnetic field direction control means capable of controlling the magnetic field direction of the permanent magnet. A rotating electrical machine comprising a stator and a rotor including a permanent magnet, the magnetic field strength control means capable of controlling the magnetic field strength of the permanent magnet with respect to the stator according to the rotational speed of the rotor, and the rotational speed of the rotor And a magnetic field direction control means capable of controlling the magnetic field direction of the permanent magnet relative to the stator,
The rotor rotates around the axis of the rotor base, a rotor magnet part that is rotatable around the axis and is provided with a permanent magnet at a position offset from the axis, and the rotor magnet part revolves around the axis of the rotor base. And a pair of rotation support members that are disposed before and after the rotor base so as to be able to rotate and support the rotor base and the rotor magnet, and the magnetic field intensity control means and the magnetic field direction control means are configured to rotate with the revolution center of the rotor magnet. rotary electric machine you being a tilting angle control means capable of controlling the tilt angle of the magnetic field direction of the permanent magnet with respect to a line connecting the center. 4. The rotating electrical machine according to claim 3 , wherein the magnetic field direction control means tilts the magnetic field direction of the permanent magnet as the rotational speed of the rotor increases. 5. The rotating electrical machine according to claim 4 , wherein the tilt angle control means increases the tilt angle in the magnetic field direction of the permanent magnet as the rotational speed of the rotor increases. The tilt angle control means includes a gear mechanism that is supported by one rotation support member and allows the rotor magnet portion to rotate, an actuator that operates the gear mechanism, and a clutch that connects and disconnects the power transmission of the actuator to the gear mechanism. The rotating electrical machine according to claim 4 or 6 , characterized in that The rotating electrical machine according to claim 7 , wherein the actuator is a motor including a rotor and a stator. The tilt angle control means includes a gear mechanism that is supported by one rotation support member and allows the rotor magnet portion to rotate, a compound planetary gear that operates the gear mechanism, and a lever that gives a command to the compound planetary gear. The rotating electrical machine according to claim 4 or 6 , characterized in that The gear mechanism is configured to include a first gear that can rotate integrally with the rotor magnet portion, and the compound planetary gear is a combination of two or more planetary gears including a sun gear, a ring gear, a pinion, and a carrier. The following conditions for the compound planetary gear: Condition 1: Select one of the sun gear, ring gear, and carrier, and one of the selected pair of parts meshes with the first gear indirectly or directly and the other supports Connected directly or indirectly to the member,
Condition 2: One of the remaining two parts selected in condition 1 is selected, and one of the selected pair of parts is coupled to the case and the other is coupled to the lever.
Condition 3: The rotating electrical machine according to claim 9 , wherein the rotating electrical machine satisfies a connection pattern that satisfies that a pair of parts not selected in Condition 2 are coupled to each other.

Images