JP7015534B2 - Magnetic gear - Google Patents

Description

The present invention relates to a magnetic gear that transmits torque using a gear that utilizes magnetism.

A general gear mechanism uses multiple gears and shifts gears according to the ratio of the number of teeth, which causes vibration and noise due to contact between teeth, has a mechanical life due to wear, and requires maintenance such as lubrication. You will need it. On the other hand, the development and practical application of magnetic gears that transmit torque in a non-contact manner using magnetism are being promoted. Since the magnetic gear transmits torque in a non-contact manner, it does not have the above-mentioned inconvenience.

As a general configuration of a magnetic gear, for example, as shown in Patent Document 1, an inner gear and an outer gear in which a plurality of magnets are arranged in the circumferential direction and a stator in which a plurality of pole pieces are arranged in the circumferential direction are provided. From the inner diameter side to the outer diameter side, the inner gear, the stator, and the outer gear are configured to be concentrically and relatively rotatable in this order. One of the inner gear, the stator, and the outer gear is used as an input unit, and any one of them is used as an output unit to shift gears and transmit rotation.

When trying to change the gear ratio with a magnetic gear, for example, in Reference 2, a plurality of sets of outer gears and inner gears having different numbers of magnetic poles are arranged in parallel in the axial direction, and a common stator is moved in the axial direction. It has been proposed to enable any one of the plurality of sets. In this magnetic gear, a gear ratio based on the number of effective outer gears and inner gears can be obtained.

Non-Patent Document 1 discloses that different gear ratios can be obtained between the case where the center rotor of the magnetic gear is fixed and the case where the outer gear is fixed, and a formula for calculating the gear ratios thereof.

Further, in the case of performing one-to-one torque transmission that does not require shifting, for example, a magnetic coupling (see Patent Document 3) may be used.

Japanese Unexamined Patent Publication No. 2017-225209 Japanese Patent No. 5381621 International Publication No. 2009/142258

Ando "Development Trends of Magnetic Gears", Journal of AEM Society of Japan, Vol24, No. 2, 2016, p. 15-20

By the way, in the magnetic gear described in Patent Document 2, a plurality of sets of outer gears and inner gears having different numbers of magnetic poles are provided in the axial direction, and a mechanism for moving the stator in the axial direction is required, which is considerably complicated and large. Become. In addition, the other sets that are not used become a heavy load, and the rotation efficiency is poor.

Further, such a magnetic gear is not suitable for preparing a plurality of variations having different fixed gear ratios according to the user's application.

Furthermore, such magnetic gears use one magnetic gear as a predetermined fixed gear ratio during a relatively long operating period and use the same magnetic gear at different fixed gear ratios and rotations during different operating periods. It is not suitable for the purpose of setting the direction.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a magnetic gear having high rotational efficiency and capable of changing a gear ratio according to an application.

In order to solve the above-mentioned problems and achieve the object, the magnetic gear according to the present invention includes an inner gear in which a plurality of inner magnets are arranged in the circumferential direction of the inner yoke and a relative rotation toward the outer peripheral side with respect to the inner gear. A center ring that is possibly provided and has a plurality of soft magnetic materials arranged in the circumferential direction of the non-magnetic cylinder, and a plurality of outers that are rotatably provided on the outer peripheral side of the center ring and are rotatably provided in the circumferential direction of the outer yoke. An outer gear in which magnets are arranged, an outer side surface portion that is non-rotatably provided on the outer gear on one side surface in the axial direction, and a center side surface portion that is non-rotatably provided on the center ring on the other side surface in the axial direction. The outer side surface portion and the center side surface portion are each provided with a shaft fixing portion capable of fixing the outer shaft. do.

The outer shaft may be provided with an inner shaft insertion hole through which the inner shaft can be inserted.

The inner shaft can be rearranged in the opposite direction to the inner gear and protrudes in either one of the axial directions, and the outer shaft is fixed to the shaft fixing portion on the non-protruding side of the inner shaft. You may.

A pair of outer shafts may be provided and fixed to the shaft fixing portions in both the outer side surface portion and the center side surface portion, and both ends of the inner shaft may protrude from the pair of inner shaft insertion holes.

The inner shaft has a shaft base fixed to the inner gear and a protruding shaft that can be connected to both ends of the shaft base in the axial direction and to which torque is transmitted from the shaft base. Is connected to one end of the shaft base and protrudes in the axial direction, and the outer shaft may be fixed to the shaft fixing portion on the non-protruding side of the protruding shaft.

The protruding shaft may be mechanically connected to the shaft base.

The protruding shaft may be magnetically connected to the shaft base in a non-contact manner.

The outer gear or the center ring may have a base for non-rotatably fixing, and the outer side surface portion or the center side surface portion may each include a base fixing portion capable of fixing the base.

At least one of the outer gear and the inner gear may be of the IPM type.

In the magnetic gear according to the present invention, the outer shaft is fixed to the shaft fixing portion of the outer side surface portion or the shaft fixing portion of the center side surface portion. As a result, the fixed portion of the outer shaft changes, and the gear ratio can be changed according to the application. Further, no additional element is required to change the gear ratio, and the rotation efficiency is good.

FIG. 1 is an exploded perspective view showing a magnetic gear according to the first embodiment. FIG. 2-1 is a cross-sectional view showing a state in which the magnetic gear according to the first embodiment is assembled so that the inner shaft protrudes from the left side surface. FIG. 2-2 is a cross-sectional view showing a state in which the magnetic gear according to the first embodiment is assembled so that the inner shaft protrudes from the right side surface. FIG. 3-1 is a partial cross-sectional perspective view showing a state in which the magnetic gear according to the first embodiment is assembled so that the inner shaft protrudes from the left side surface. FIG. 3-2 is a partial cross-sectional perspective view showing a state in which the magnetic gear according to the first embodiment is assembled so that the inner shaft protrudes from the right side surface. FIG. 4 is a partially enlarged front view of the outer gear, the inner gear, and the center ring of the magnetic gear. FIG. 5 is an exploded perspective view showing the magnetic gear according to the second embodiment. FIG. 6 is a cross-sectional view showing a magnetic gear according to the second embodiment. FIG. 7-1 is a partial cross-sectional perspective view showing a state in which the center ring is fixed, which is the magnetic gear according to the second embodiment. FIG. 7-2 is a partial cross-sectional perspective view showing a state in which the outer gear is fixed, which is the magnetic gear according to the second embodiment. FIG. 8-1 is a cross-sectional view showing a state in which the magnetic gear according to the third embodiment is assembled so that the inner shaft protrudes from the left side surface. FIG. 8-2 is a cross-sectional view showing a state in which the magnetic gear according to the third embodiment is assembled so that the inner shaft protrudes from the right side surface. FIG. 9-1 is a cross-sectional view showing a state in which the magnetic gear according to the fourth embodiment is assembled so that the inner shaft protrudes from the left side surface. FIG. 9-2 is a cross-sectional view showing a state in which the magnetic gear according to the fourth embodiment is assembled so that the inner shaft protrudes from the right side surface. FIG. 10-1 is a cross-sectional view showing a state in which the magnetic gear according to the fifth embodiment is assembled so that the inner shaft protrudes from the left side surface. FIG. 10-2 is a cross-sectional view showing a state in which the magnetic gear according to the fifth embodiment is assembled so that the inner shaft protrudes from the right side surface.

Hereinafter, embodiments of the magnetic gear according to the present invention will be described in detail with reference to the drawings. The present invention is not limited to this embodiment. Hereinafter, in order to identify the direction, the upper right direction is the X1 direction and the lower left direction is the X2 direction with respect to the axial direction in FIG. 1, and an arrow indicating the direction is shown in each figure. All bolts are called bolts B regardless of size and type.

As shown in FIGS. 1, 2-1 and 3-1 the magnetic gear 10a according to the first embodiment includes an outer gear body 12, an inner gear 14, a center body 16, and an outer shaft 18. It has an inner shaft 20 and a base 22.

The outer gear body 12 has a casing 24, an outer gear 26, and an outer side surface portion 28. The casing 24 is a tubular body, and forms the outer frame of the main body of the magnetic gear 10a except for the base 22.

The outer gear 26 has an outer yoke 26a and an outer magnet 26b having NL = 31 pole pairs (62 pieces). The outer yoke 26a is a soft magnetic material, and is a tubular body fixed to the inner peripheral surface of the casing 24. The outer magnet 26b is embedded in the outer yoke 26a so as to have a long shape in the radial direction, and has a radial shape arrangement at equal angles in the circumferential direction. The outer magnet 26b is magnetized in the circumferential tangential direction, that is, in the short direction, and the adjacent magnets are arranged in directions in which the magnetizing directions are opposite to each other. See FIG. 4). The outer gear 26 is also called a low speed rotor.

The outer side surface portion 28 is a lid covering the X1 direction side of the magnetic gear 10a, is fixed to the X1 direction end surface of the casing 24 by a plurality of bolts B, and is non-rotatable and integrally rotates with respect to the outer gear 26. The outer side surface portion 28 has a central hole 28a through which the inner shaft 20 can be inserted, a shaft fixing portion 28b which is six bolt holes arranged at equal angles, and a base fixing portion 28c which is six bolt holes. The shaft fixing portion 28b can fix the outer shaft 18 by the bolt B. The base fixing portion 28c is arranged on the outer diameter side of the shaft fixing portion 28b, and can be fixed to the base 22 by bolts B (see FIG. 2-2). An annular protrusion 28d projecting in the X1 direction is provided between the shaft fixing portion 28b and the base fixing portion 28c, and a fitting groove 28e shallower on the inner diameter side than the annular protrusion 28d is formed. The shaft fixing portion 28b is provided at the bottom of the fitting groove 28e.

The inner gear 14 has an inner yoke 14a and an inner magnet 14b having NH = 3 pole pairs (6 pieces). The inner yoke 14a is a soft magnetic material and has a disk shape. The inner magnet 14b is embedded in the inner yoke 14a so as to have a long shape in the radial direction, and has a radial shape arrangement at equal angles in the circumferential direction. Inner magnet 14b is magnetized in the circumferential tangential direction, that is, in the short direction, and adjacent magnets are arranged in directions in which the magnetizing directions are opposite, and the S poles face each other and the N poles face each other in the circumferential direction (Fig.). 4). An inner shaft fixing hole 15 through which the inner shaft 20 is inserted and fixed is provided at the center of the inner gear 14. The inner gear 14 is also called a high-speed rotor.

The center body 16 has a center ring 30 and a center side surface portion 32. The center ring 30 has a pole holder 30a and NS = 34 pole pieces 30b. The pole holder 30a is a non-magnetic cylinder. The pole piece 30b is a soft magnetic material and is arranged at an equal angle in the circumferential direction with respect to the pole holder 30a. The inner yoke 14a, the inner magnet 14b, the outer yoke 26a, the outer magnet 26b, and the pole piece 30b are set so that their axial positions and axial lengths are substantially equal to each other (see FIG. 2-1).

The pole logarithm NL of the outer magnet 26b in the outer gear 26, the pole logarithm NH of the inner magnet 14b in the inner gear 14, and the number NS of the pole pieces 30b in the center ring 30 are determined.
NS = NL ± NH
Is selected so that the relationship is established.
In the magnetic gear 10a, NS = 34, NL = 31, NH = 3, and so on.
34 = 31 + 3
The relationship is established.

The center side surface portion 32 is a lid that covers the X2 direction side of the magnetic gear 10a. The center ring 30 and the center side surface portion 32 are integrally molded and cannot rotate relative to each other, and the outer peripheral portion of the center side surface portion 32 is connected to the X2 direction end surface of the center ring 30. The center side surface portion 32 includes a center hole 32a through which the inner shaft 20 can be inserted, a shaft fixing portion 32b which is six bolt holes arranged at equal angles, and a base fixing portion which is six bolt holes arranged at equal angles. It has 32c and. The shaft fixing portion 32b can fix the outer shaft 18 by the bolt B. The base fixing portion 32c is arranged on the outer diameter side of the shaft fixing portion 32b, and is fixed to the base 22 by the bolt B. An annular protrusion 32d protruding in the X2 direction is provided between the shaft fixing portion 32b and the base fixing portion 32c, and a fitting groove 32e shallower on the inner diameter side than the annular protrusion 32d is formed. The shaft fixing portion 32b is provided at the bottom of the fitting groove 32e.

The six shaft fixing portions 32b and the above six shaft fixing portions 28b have the same shape and arrangement when viewed from the axial direction, and the outer shaft 18 can be fixed to each. The six base fixing portions 32c and the above six base fixing portions 28c have the same shape and the same arrangement when viewed from the axial direction, and the base 22 can be fixed respectively.

The center side surface portion 32 has the same symmetrical structure as the inner diameter side portion excluding the vicinity of the outer peripheral side surface portion 28, and includes the center hole 28a and the center hole 32a, the shaft fixing portion 28b and the shaft fixing portion 32b, and the base fixing portion 28c. The base fixing portion 32c, the annular protrusion 28d and the annular protrusion 32d, and the fitting groove 28e and the fitting groove 32e have the same shape and are arranged in the same manner.

The outer shaft 18 and the inner shaft 20 are input / output units to which a drive mechanism and a driven mechanism are connected. The outer shaft 18 has a flange 18a, a shaft portion 18b protruding from the flange 18a on one side, and six holes 18c provided in the flange 18a at equal intervals. When the bolt B is screwed into the shaft fixing portion 28b through the hole 18c, the outer shaft 18 is fixed to the outer side surface portion 28, and the shaft portion 18b projects in the X1 direction. The flange 18a is fitted into the fitting groove 28e and is stabilized. The outer shaft 18 can be fixed to either the outer side surface portion 28 or the center side surface portion 32 and can also be called an outer / center combined shaft or a low speed shaft, but here, it is simply referred to as an outer shaft 18. The same applies to the outer shaft 42 described later.

The inner shaft 20 has a long cylindrical shaft shape, is mechanically connected to the inner shaft fixing hole 15 (for example, a key, a spline, and a D-cut structure), and is non-rotatable and integral with the inner gear 14. Rotate to. The inner shaft 20 is removable from the inner shaft fixing hole 15 and can be rearranged in the opposite direction in the axial direction. The vicinity of the end portion of the inner shaft 20 in the X1 direction is pivotally supported by a bearing 34a with respect to the central hole 28a of the outer side surface portion 28. A substantially central portion of the inner shaft 20 is pivotally supported by a bearing 34b with respect to the central hole 32a of the center side surface portion 32. Spacers 36a and 36b are interposed between the inner ring of the bearings 34a and 34b and the inner gear 14, respectively. The bearings 34a and 34b are treated with snap rings 38a and 38b to prevent them from coming off. The inner gear 14 can rotate relative to the outer gear body 12 and the center body 16 by the bearings 34a and 34b. The inner shaft 20 may also be referred to as a high speed shaft.

A bearing 40a is provided between a part of the outer side surface portion 28 and the inner peripheral surface of the center ring 30 at the end in the X1 direction. A bearing 40b is provided between the outer peripheral surface of the X2 direction end of the center side surface portion 32 and the inner peripheral surface of the X2 direction end of the casing 24. The bearings 40a and 40b allow the outer gear body 12 and the center body 16 to rotate relative to each other.

The base 22 has a function as a fixed base, is L-shaped in a side view, and has a side plate 22a and a base plate 22b. The side plate 22a stands orthogonal to the base plate 22b. The side plate 22a has a shaft insertion hole 22c provided in the center and six holes 22d provided at equal angles around the shaft insertion hole 22c. When the bolt B is screwed into the base fixing portion 32c through the hole 22d, the base 22 is fixed to the center side surface portion 32. The shaft insertion hole 22c has a diameter through which the outer shaft 18, the flange 18a and the inner shaft 20 can be inserted. A shallow annular notch 22e is provided at one end of the shaft insertion hole 22c, and the annular protrusion 28d or the annular protrusion 32d can be fitted into the annular notch 22e. The shaft insertion hole 22c and the fitting grooves 28e and 32e have the same diameter.

As shown in FIGS. 2-1 and 3-1 the outer shaft 18 is fixed to the outer side surface portion 28 of the outer gear body 12, and the shaft portion 18b projects in the X1 direction. The inner shaft 20 is fixed to the inner shaft fixing hole 15 of the inner gear 14, and is assembled so as to project in the X2 direction through the center hole 32a and the shaft insertion hole 22c. The outer shaft 18 and the inner shaft 20 have a coaxial structure. The base 22 is fixed to the center side surface portion 32 of the center body 16. By assembling the magnetic gear 10a in this way, the outer gear body 12 to which the outer shaft 18 is integrally fixed becomes the low speed side input / output unit, and the inner gear 14 to which the inner shaft 20 is integrally fixed becomes the high speed side input / output unit. Become. The torque of rotation is transmitted between the outer shaft 18 and the inner shaft 20 by shifting gears by the magnetic action of the outer gear body 12, the inner gear 14, and the center ring 30.

At this time, the gear ratio Gr when the outer shaft 18 is on the input side and the inner shaft 20 is on the output side can be obtained by the following equation.
Gr = -NL / NH = -31/3 = -10.33
That is, the absolute value of the gear ratio Gr is 10.33, which is a minus sign, so that the rotation direction is opposite. The same applies to the state shown in FIG. 8-1 of the magnetic gear 10b, which will be described later, the state shown in FIG. 9-1 of the magnetic gear 10c, and the state shown in FIG. 10-1 of the magnetic gear 10e.

On the other hand, as shown in FIGS. 2-2 and 3-2, the outer shaft 18 can also be fixed to the center side surface portion 32 of the center body 16, and in this case, the shaft portion 18b projects in the X2 direction. The inner shaft 20 is fixed to the inner shaft fixing hole 15 of the inner gear 14, and is assembled so as to project in the X1 direction through the center hole 28a and the shaft insertion hole 22c. Also in this case, the outer shaft 18 and the inner shaft 20 have a coaxial structure. The base 22 is fixed to the outer side surface portion 28 of the outer gear body 12. By assembling the magnetic gear 10a in this way, the center body 16 to which the outer shaft 18 is integrally fixed becomes the low speed side input / output unit, and the inner gear 14 to which the inner shaft 20 is integrally fixed becomes the high speed side input / output unit. .. The torque of rotation is transmitted between the outer shaft 18 and the inner shaft 20 by shifting gears by the magnetic action of the outer gear body 12, the inner gear 14, and the center ring 30.

At this time, the gear ratio Gr is calculated by the following equation.
Gr = NS / NH = 34/3 = + 11.33
That is, the absolute value of the gear ratio Gr is 11.33, and since it is a plus sign, the rotation direction is forward. The same applies to the state shown in FIG. 8-2 of the magnetic gear 10b, which will be described later, the state shown in FIG. 9-2 of the magnetic gear 10c, and the state shown in FIG. 10-2 of the magnetic gear 10e. The principle of obtaining a speed change operation by the magnetic action of the magnetic gears 10a to 10e is known, for example, as shown in Patent Document 1 and Non-Patent Document 1, and thus description thereof will be omitted here.

As shown in FIG. 4, the inner gear 14 and the outer gear 26 of the magnetic gear 10a are IPM type (Interior Permanent Magnet, magnet embedded type). That is, the inner magnet 14b in the inner gear 14 and the outer magnet 26b in the outer gear 26 are embedded in the radial direction of the inner yoke 14a and the outer yoke 26a and arranged radially, and the N pole and the S pole are respectively arranged in the circumferential direction. It is suitable. In such an IPM type structure, a magnet is arranged on the surface of each rotor, and a higher torque can be obtained as compared with the SPM type (Surface Permanent Magnet, surface magnet type) in which the magnetizing direction of the magnet is the radial direction. In addition, high efficiency is achieved because the eddy current loss is small. Further, since the inner magnet 14b and the outer magnet 26b have an embedded structure, there is no concern that they will be peeled off due to the action of centrifugal force, and they are suitable for high-speed rotation. Further, if at least one of the inner gear 14 and the outer gear 26 has an IPM type structure, the above effect can be obtained accordingly. In FIG. 4, in the outer magnet 26b and the inner magnet 14b, the north pole is identified as a dot and the south pole is identified as a white background for easy understanding.

According to the magnetic gear 10a configured as described above, the outer shaft 18 can be fixed to either the outer side surface portion 28 in the X1 direction or the center side surface portion 32 in the X2 direction, whereby the outer gear body 12 or the center body can be fixed. Any one of 16 can be selected as the low speed side input / output unit. Further, the inner shaft 20 which is the high-speed side input / output portion of the inner gear 14 can be assembled so as to project to the side opposite to the shaft portion 18b of the outer shaft 18. This makes it possible to select the gear ratio and the rotation direction. In particular, the magnetic gear 10a is suitable for applications in which one magnetic gear 10a is used as a predetermined fixed gear ratio during a relatively long operation period, and the same magnetic gear 10a is used as a different fixed gear ratio during different operation periods. .. Further, it is suitable for arranging a plurality of variations having different fixed gear ratios or rotation directions according to the user's application.

The magnetic gear 10a can change the gear ratio only by changing the assembly positions of the outer shaft 18, the inner shaft 20 and the base 22, and since there are no additional elements that are not used, there is no wasteful weight load and the rotation efficiency is good.

In the magnetic gear 10a, the gear ratio Gr is 10.33 or 11.33 in absolute value, which are relatively close values. Therefore, it is suitable for fine adjustment of the gear ratio Gr. It is also possible to increase the difference between the two gear ratio Grs by selecting NL, NH and NS.

If the inner shaft insertion hole 42d (see FIG. 5) in the outer shaft 42 of the magnetic gear 10b, which will be described later, is provided with an appropriately large diameter with respect to the outer shaft 18, the outer shaft 18 will be formed with respect to the inner shaft 20. It does not interfere regardless of its protruding direction. In this way, the outer shaft 18 and the inner shaft 20 (and the protruding shafts 48, 52, 60 described later) can be projected in the same direction. In this case, the outer shaft 18 does not need to be detachable from the outer side surface portion 28 and the center side surface portion 32, and may be integrally molded. The same applies to the magnetic gears 10c, 10d, and 10e described later.

The outer shaft 18 may be provided with various variations according to the shape of the drive mechanism or the driven mechanism to be connected. Further, the drive mechanism or the driven mechanism connected to the magnetic gear 10a is not necessarily connected to the outer shaft 18, for example, directly to the shaft fixing portion 28b or the shaft fixing portion 32b without passing through the outer shaft 18. You may connect. In this case, the connected drive mechanism or driven mechanism is equated with the outer shaft 18. The same applies to the outer shaft 42 described later.

Next, the magnetic gear 10b according to the second embodiment will be described with reference to FIGS. 5 to 7-1 and 7-2. Regarding the magnetic gear 10b and the magnetic gears 10c, 10d, and 10e described later, the same components as those of the magnetic gear 10a described above are designated by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIGS. 5, 6 and 7-1 and 7-2, the magnetic gear 10b is provided with a pair of outer shafts 42 in place of the one outer shaft 18 in the magnetic gear 10a, and the inner shaft 20 is provided. The inner shaft 44 is provided instead of the above.

Each of the pair of outer shafts 42 has a flange 42a, a shaft portion 42b protruding from the flange 42a on one side, six holes 42c provided in the flange 42a at equal intervals, and an inner shaft insertion hole 42d. The flange 42a, the shaft portion 42b, and the hole 42c correspond to the flange 18a, the shaft portion 18b, and the hole 18c described above. That is, the outer shaft 42 is further provided with an inner shaft insertion hole 42d with respect to the outer shaft 18. The inner shaft insertion hole 42d is provided in the center of the outer shaft 42, and has a diameter through which the inner shaft 44 can be inserted.

One of the pair of outer shafts 42 is fixed to the outer side surface portion 28 of the outer gear body 12, and the shaft portion 42b projects in the X1 direction. The other of the pair of outer shafts 42 is fixed to the center side surface portion 32 of the center body 16, and the shaft portion 42b projects in the X2 direction.

The inner shaft 44 is longer than the inner shaft 20 and has a symmetrical shape centered on the fixing portion of the inner gear 14 with respect to the inner shaft fixing hole 15. That is, the inner shaft 20 protrudes in either the X1 direction or the X2 direction when fixed in the inner shaft fixing hole 15, whereas the inner shaft 44 protrudes in both the X1 direction and the X2 direction. .. Since the inner shaft insertion hole 42d is provided at the center of the outer shaft 42 provided in both the X1 direction and the X2 direction, the inner shaft 44 can project to both sides without interfering with the outer shaft 42. There is. Both ends of the inner shaft 44 project appropriately from the ends of the outer shaft 42, and a drive portion or a driven portion can be connected.

As shown in FIG. 7-1, when the base 22 is fixed to the center side surface portion 32 of the center body 16, the outer gear body 12 to which the outer shaft 42 on the X1 side is integrally fixed becomes the low speed side input / output portion, and the inner shaft 44 The inner gear 14 to which is integrally fixed serves as a high-speed side input / output unit. As the inner shaft 44, either the X1 side protruding portion or the X2 side protruding portion may be used.

As shown in FIG. 7-2, when the base 22 is fixed to the outer side surface portion 28 of the outer gear body 12, the center body 16 to which the outer shaft 42 on the X2 side is integrally fixed becomes the low speed side input / output portion, and the inner shaft 44 The inner gear 14 to which is integrally fixed serves as a high-speed side input / output unit. As the inner shaft 44, either the X1 side protruding portion or the X2 side protruding portion may be used.

According to the magnetic gear 10b configured in this way, the gear ratio Gr and the rotation direction can be changed only by changing the fixed position of the base 22 without rearranging the outer shaft 42 and the inner shaft 44.

When the base 22 is fixed to the center side surface portion 32 as shown in FIG. 7-1, the outer shaft 42 on the X2 side is not used and may be removed. Similarly, when the base 22 is fixed to the outer side surface portion 28 as shown in FIG. 7-2, the outer shaft 42 on the X1 side is not used and may be removed. By removing the outer shaft 42 on the unused side, the weight is reduced accordingly. In this case, the inner shaft 44 may be shortened and may have a length that does not protrude from the end of the outer shaft 42. Further, the outer shaft 42 on the X1 side does not necessarily have to be detachable from the outer side surface portion 28, and may be integrally molded. The outer shaft 42 on the X2 side does not necessarily have to be detachable from the center side surface portion 32, and may be integrally molded.

Next, the magnetic gear 10c according to the third embodiment will be described with reference to FIGS. 8-1 and 8-2. As shown in FIGS. 8-1 and 8-2, the magnetic gear 10c is provided with an inner shaft 45 instead of the inner shaft 20 in the magnetic gear 10a described above. The inner shaft 45 includes a shaft base 46 and a protruding shaft 48. The shaft base 46 corresponds to the fixing portion of the inner shaft 20 with the inner shaft fixing hole 15. The shaft base 46 has a symmetrical shape, and the end in the X1 direction is in the center hole 28a of the outer side surface portion 28, and the end in the X2 direction is in the center hole 32a of the center side surface portion 32. A spline groove 46a and a spline groove 46b are provided at each axis center portion of the X1 direction end and the X2 direction end of the shaft base 46. The protruding shaft 48 corresponds to the protruding portion of the inner shaft 20 described above, and a spline tooth 48a capable of meshing with the spline grooves 46a and 46b is provided at one end thereof. The protruding shaft 48 may be movable in the axial direction by using the characteristics of the spline. The meshing between the spline teeth 48a and the spline groove 46a may be a press-fit serration type.

As shown in FIG. 8-1, the protruding shaft 48 protrudes in the X2 direction by engaging and fitting the spline teeth 48a with the spline groove 46b on the X2 direction side of the shaft base 46. In this case, the outer shaft 18 is fixed to the outer side surface portion 28 of the outer gear body 12, and the shaft portion 18b projects in the X1 direction. The outer shaft 18 does not interfere with the shaft base 46. Then, when the base 22 is fixed to the center side surface portion 32 of the center body 16, the outer gear body 12 to which the outer shaft 18 is integrally fixed becomes the low speed side input / output portion, and the protruding shaft 48 is integrally fixed via the shaft base 46. The inner gear 14 serves as a high-speed side input / output unit.

As shown in FIG. 8-2, the protruding shaft 48 protrudes in the X1 direction by engaging and fitting the spline teeth 48a with the spline groove 46b on the X1 direction side of the shaft base 46. In this case, the outer shaft 18 is fixed to the center side surface portion 32 of the center body 16, and the shaft portion 18b projects in the X2 direction. The outer shaft 18 does not interfere with the shaft base 46. Then, when the base 22 is fixed to the outer side surface portion 28 of the outer gear body 12, the center body 16 to which the outer shaft 18 is integrally fixed becomes the low speed side input / output portion, and the protruding shaft 48 is integrally fixed via the shaft base 46. The inner gear 14 serves as a high-speed side input / output unit.

According to the magnetic gear 10c configured in this way, the spline teeth 48a of the protruding shaft 48 are mechanically fixed to either the spline groove 46a or the spline groove 46b, so that the protruding shaft does not disassemble the main body. The protruding direction of 48 can be changed. Further, by mechanical fixing, the protruding shaft 48 and the shaft base 46 are securely fastened. Then, the outer shaft 18 is attached in the direction opposite to the direction in which the protruding shaft 48 protrudes, and the gear ratio Gr and the rotation direction can be changed only by changing the fixed position of the base 22. The means for fixing the protruding shaft 48 and the shaft base 46 is not limited to the spline structure, and fitting of non-circular cross-section portions such as a D-cut type can be applied.

The protruding shaft 48 may be provided with various variations according to the shape of the driven mechanism or the driven mechanism to be connected. Further, the drive mechanism or the driven mechanism connected to the magnetic gear 10c is not necessarily connected to the protruding shaft 48, and may be directly connected to the shaft base 46 without, for example, via the protruding shaft 48. In this case, the connected drive mechanism or driven mechanism is equated with the protruding shaft 48. The protruding shafts 52 and 60, which will be described later, can be omitted in the same manner, and a drive mechanism or a driven mechanism that is equated with the protruding shafts 52 and 60 may be directly connected to the shaft bases 50 and 58.

Next, the magnetic gear 10d according to the fourth embodiment will be described with reference to FIGS. 9-1 and 9-2. As shown in FIGS. 9-1 and 9-2, the magnetic gear 10d is provided with an inner shaft 49 instead of the inner shaft 20 in the magnetic gear 10a. The inner shaft 49 includes a shaft base 50 and a protruding shaft 52. The shaft base 50 corresponds to the fixing portion of the inner shaft 20 with the inner shaft fixing hole 15. The shaft base 50 has a symmetrical shape, and the shaft length is set as short as the shaft base 46 (see FIGS. 8-1 and 8-2), and there is no interference with the outer shaft 18. The shaft base 50 has a shallow fitting groove 54a at the end in the X1 direction and a shaft fixing portion 56a provided at the bottom of the fitting groove 54a, and similarly has a shallow fitting groove 54b at the end in the X2 direction. It has a shaft fixing portion 56b provided at the bottom of the fitting groove 54b. The shaft fixing portions 56a and 56b are six bolt holes arranged at equal angles.

The protruding shaft 52 corresponds to the protruding portion of the inner shaft 20 described above, and includes a flange 52a, a shaft portion 52b protruding unilaterally from the flange 52a, and six equally spaced holes 52c provided in the flange 52a. Have. The shaft fixing portions 56a and 56b correspond to the holes 52c, and the protruding shaft 52 is fixed to the shaft base 50 by inserting the bolts B through the holes 52c and screwing them into the shaft fixing portions 56a or 56b. The flange 52a fits into the fitting groove 54a or 54b. The shaft base 50 has an appropriately large diameter in order to form fitting grooves 54a and 54b that fit the flange 52a.

As shown in FIG. 9-1, when the bolt B is screwed into the shaft fixing portion 56b through the hole 52c, the protruding shaft 52 is fixed to the X2 direction end of the shaft base 50, and the shaft portion 52b is in the X2 direction. Protrude. The flange 52a is fitted into the fitting groove 54b and is stabilized. In this case, the outer shaft 18 and the base 22 are assembled in the same manner as in the state of the magnetic gear 10c shown in FIG. 8-1, and the outer gear body 12 to which the outer shaft 18 is integrally fixed becomes the low speed side input / output unit and protrudes. The inner gear 14 in which the shaft 52 is integrally fixed via the shaft base 50 serves as the high-speed side input / output unit.

As shown in FIG. 9-2, when the bolt B is screwed into the shaft fixing portion 56a through the hole 52c, the protruding shaft 52 is fixed to the X1 direction end of the shaft base 50, and the shaft portion 52b is in the X1 direction. Protrude. The flange 52a fits into the fitting groove 54a and is stable. In this case, the outer shaft 18 and the base 22 are assembled in the same manner as in the state of the magnetic gear 10c shown in FIG. 8-2, and the center body 16 to which the outer shaft 18 is integrally fixed becomes the low speed side input / output unit and the protruding shaft. The inner gear 14 to which the 52 is integrally fixed via the shaft base 50 serves as the high-speed side input / output unit.

According to the magnetic gear 10d configured as described above, the protruding shaft is formed by inserting a bolt B into the hole 52c, screwing it into either the shaft fixing portion 56a or the shaft fixing portion 56b, and mechanically fixing the bolt B. 52, The protruding direction of the protruding shaft 52 can be changed without disassembling the main body. Further, the protruding shaft 52 and the shaft base 50 are securely fastened by mechanical fixing. Then, the outer shaft 18 is attached in the direction opposite to the direction in which the protruding shaft 52 protrudes, and the gear ratio Gr and the rotation direction can be changed only by changing the fixed position of the base 22. The protrusion shaft 52 can be easily and reliably attached to and detached from the shaft base 50 by using a bolt B, which is a standard component. The protruding shaft 52 and the shaft base 50 have a simple shape and are easy to manufacture.

Next, the magnetic gear 10e according to the fifth embodiment will be described with reference to FIGS. 10-1 and 10-2. As shown in FIGS. 10-1 and 10-2, the magnetic gear 10e is provided with an inner shaft 57 in place of the inner shaft 20 in the magnetic gear 10a, and further provided with a base 62 in place of the base 22. Is. The inner shaft 57 includes a shaft base 58 and a protruding shaft 60. The shaft base 58 corresponds to the fixing portion of the inner shaft 20 with the inner shaft fixing hole 15. The shaft base 58 has a symmetrical shape, and the shaft length is set as short as the shaft base 46 (see FIGS. 8-1 and 8-2), and there is no interference with the outer shaft 18. The shaft base 58 has a disk magnet 58a provided at the end in the X1 direction and a disk magnet 58b provided at the end in the X2 direction. The protruding shaft 60 corresponds to the protruding portion of the inner shaft 20 and has a disk magnet 60a at one end. The disk magnets 58a, 58b, and 60a each have a structure in which a plurality of magnetic poles are arranged in the circumferential direction.

In the base 62, the portion of the side plate 22a in the base 22 is replaced with the side plate 62a. The side plate 62a has a tubular portion 62b provided in the central portion and projecting to one side, a shaft insertion hole 62c provided in the tubular portion 62b, and six holes provided at equal angles around the shaft insertion hole 62c. It has 62d and an annular notch 62e. The shaft insertion hole 62c, the hole 62d and the annular notch 62e correspond to the above-mentioned shaft insertion hole 22c, the hole 22d and the annular notch 22e. A bearing 63a and a bearing 63b are provided on the inner peripheral surface of the shaft insertion hole 62c, and the protruding shaft 60 is rotatably supported.

As shown in FIG. 10-1, when the bolt B is screwed into the base fixing portion 32c through the hole 62d, the disk magnet 60a of the protruding shaft 60 is arranged to face the disk magnet 58b of the shaft base 58 with a gap. Will be done. The protruding shaft 60 protrudes in the X2 direction by an appropriate amount. The outer shaft 18 is fixed to the outer side surface portion 28 of the outer gear body 12, and the shaft portion 18b projects in the X1 direction. The outer shaft 18 does not interfere with the disk magnet 58a. The disk magnet 60a and the disk magnet 58b form a magnetic coupling 64a, and can magnetically transmit torque in a non-contact manner. In such an assembled state, the outer gear body 12 to which the outer shaft 18 is integrally fixed becomes the low speed side input / output unit, and the inner gear 14 in which the protruding shaft 60 is fixed to the shaft base 58 via the magnetic coupling 64a is high speed. It becomes a side input / output unit.

As shown in FIG. 10-2, when the bolt B is screwed into the base fixing portion 28c through the hole 62d, the disk magnet 60a of the protruding shaft 60 is arranged to face the disk magnet 58a of the shaft base 58 with a gap. Will be done. The protruding shaft 60 protrudes in the X1 direction by an appropriate amount. The outer shaft 18 is fixed to the center side surface portion 32 of the center body 16, and the shaft portion 18b projects in the X2 direction. The outer shaft 18 does not interfere with the disk magnet 58b. The disk magnet 60a and the disk magnet 58a form a magnetic coupling 64b, and can magnetically transmit torque in a non-contact manner. In such an assembled state, the center body 16 to which the outer shaft 18 is integrally fixed becomes the low-speed side input / output unit, and the inner gear 14 in which the protruding shaft 60 is fixed to the shaft base 58 via the magnetic coupling 64b is on the high-speed side. It becomes an input / output unit. The magnetic couplings 64a and 64b are known, and may be configured as shown in Patent Document 3, for example.

According to the magnetic gear 10e configured in this way, no mechanical connection is required between the shaft base 58 and the protruding shaft 60, and the base 62 is simply fixed to the center side surface portion 32 or the outer side surface portion 28 to project. The shaft 60 is arranged in an appropriate position. Since the magnetic couplings 64a and 64b can transmit torque in a non-contact manner, there is no noise or wear, maintenance is free, and some misalignment is allowed. A permeable magnetic film 66 as shown by a virtual line may be provided in the vicinity of the front surface of the disk magnets 58a and 58b in the central holes 28a and 32a to protect the inside. The magnetic torque transmitting means may be provided not only on the protruding shaft 60 but also on the outer shaft 18. That is, torque may be transmitted by providing the shaft portion 18b with a magnetic coupling 68 as shown by a virtual line. In this case, the outer shaft 18 itself may be formed of a magnet and used as a part of the magnetic coupling 68.

The present invention is not limited to the above-described embodiment, and it is needless to say that the present invention can be freely changed without departing from the gist of the present invention.

10a, 10b, 10c, 10d, 10e Magnetic gear 12 Outer gear body 14 Inner gear 14a Inner yoke 14b Inner magnet 16 Center body 18,42 Outer shaft 20,44,45,49,57 Inner shaft 22,62 Base 22c Shaft insertion Hole 24 Casing 26 Outer gear 26a Outer yoke 26b Outer magnet 28 Outer side surface part 28a, 32a Center hole 28b, 32b Shaft fixing part 28c, 32c Base fixing part 30 Center ring 30a Pole holder (non-magnetic cylinder)
30b Pole piece (soft magnetic material)
32 Center side surface 42d Inner shaft insertion hole 46a, 46b Spline groove 46, 50, 58 Shaft base 48, 52, 60 Protruding shaft 56a, 56b Shaft fixing part 58a, 58b, 60a Disc magnet 64a, 64b, 68 Magnetic coupling

Claims (9)

An inner gear with multiple inner magnets arranged in the circumferential direction of the inner yoke,
A center ring that is rotatably provided on the outer peripheral side of the inner gear and has a plurality of soft magnetic materials arranged in the circumferential direction of the non-magnetic cylinder.
An outer gear that is rotatably provided on the outer peripheral side of the center ring and has a plurality of outer magnets arranged in the circumferential direction of the outer yoke.
On one side surface in the axial direction, the outer side surface portion provided on the outer gear so as not to rotate, and the outer side surface portion.
On the other side surface in the axial direction, a center side surface portion provided on the center ring so as not to rotate, and a center side surface portion.
An inner shaft provided at the center of the inner gear so as not to rotate,
Have,
The outer side surface portion and the center side surface portion are magnetic gears, each of which is provided with a shaft fixing portion capable of fixing the outer shaft. In the magnetic gear according to claim 1,
The outer shaft is a magnetic gear having an inner shaft insertion hole through which the inner shaft can be inserted. In the magnetic gear according to claim 1 or 2.
The inner shaft can be rearranged in the opposite direction to the inner gear and protrudes in either of the axial directions.
The outer shaft is a magnetic gear characterized in that it is fixed to the shaft fixing portion on the non-projecting side of the inner shaft. In the magnetic gear according to claim 2,
A pair of the outer shafts are provided and fixed to the shaft fixing portions on both the outer side surface portion and the center side surface portion.
The inner shaft is a magnetic gear having both ends protruding from the pair of inner shaft insertion holes. In the magnetic gear according to claim 1 or 2.
The inner shaft is
The shaft base fixed to the inner gear and
A protruding shaft that can be connected to either end of the shaft base in the axial direction and to which torque is transmitted from the shaft base,
Have,
The protruding shaft is connected to one end of the shaft base and protrudes in the axial direction.
The outer shaft is a magnetic gear characterized in that it is fixed to the shaft fixing portion on the non-protruding side of the protruding shaft. In the magnetic gear according to claim 5,
The protruding shaft is a magnetic gear characterized by being mechanically connected to the shaft base. In the magnetic gear according to claim 5,
The protruding shaft is a magnetic gear characterized in that it is magnetically connected to the shaft base in a non-contact manner. In the magnetic gear according to any one of claims 1 to 7.
It has a base that immobilizes the outer gear or the center ring and
The outer side surface portion or the center side surface portion is a magnetic gear, each of which is provided with a base fixing portion capable of fixing the base. The magnetic gear according to any one of claims 1 to 8.
A magnetic gear characterized in that at least one of the outer gear and the inner gear is an IPM type.

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