Magnetic gear, actuator unit having the same, and link mechanism using the same

1 . A magnetic gear, comprising: a first magnetic pole array that includes first N poles and first S poles alternately arranged at given intervals along a circumferential direction of an outer peripheral surface of a rotary disc; and a second magnetic pole array that is arranged adjacent to the first magnetic pole array along the circumferential direction and that includes second N poles and second S poles alternately arranged at given intervals, one of the second N poles of the second magnetic pole array being positioned at a location corresponding to an intermediate position between a corresponding one of the first N poles and a corresponding one of the first S poles of the first magnetic pole array, the corresponding one of the first N poles and the corresponding one of the first S poles being adjacent to each other. 2 . The magnetic gear as set forth in claim 1 , wherein: the first N poles, the first S poles, the second N poles, and the second S poles each have a columnar shape, and are buried in the outer peripheral surface along their respective axial directions. 3 . The magnetic gear as set forth in claim 1 , wherein: the rotary disc is in form of a truncated cone; the first magnetic pole array and the second magnetic pole array are arranged on an outer peripheral inclined surface of the rotary disc that is in form of the truncated cone; and the magnetic gear is a bevel gear. 4 . The magnetic gear as set forth in claim 1 , wherein: the rotary disc is made of an aluminum material or a resin material. 5 . A magnetic gear, comprising: a plurality of magnet units arranged along a circumferential direction of an outer peripheral surface of a rotary disc, each of the plurality of magnet units including a plurality of magnets arranged in a Halbach array with which directions of magnetic poles are optimized so as to strengthen a magnetic field strength on an outer side of the outer peripheral surface. 6 . The magnetic gear as set forth in claim 5 , wherein: each of the plurality of magnet units is in form of a rectangular parallelepiped, and is bonded to the outer peripheral surface. 7 . The magnetic gear as set forth in claim 5 , wherein: the rotary disc is in form of a truncated cone; the plurality of magnet units are arranged on an outer peripheral inclined surface of the rotary disc that is in form of the truncated cone; and the magnetic gear is a bevel gear. 8 . The magnetic gear as set forth in claim 5 , wherein: the rotary disc is made of an aluminum material or a resin material. 9 . The magnetic gear as set forth in claim 7 , wherein: the plurality of magnet units are arranged along a direction diagonal to a rotating shaft of the rotary disc as viewed in a direction intersecting with the rotating shaft. 10 . An actuator unit, comprising: a motor; a first magnetic gear connected to a rotating shaft of the motor; a second magnetic gear configured to be magnetically engaged with the first magnetic gear; and a planetary reducer connected to a rotating shaft of the second magnetic gear, each of the first magnetic gear and the second magnetic gear being a magnetic gear recited in claim 1 . 11 . The actuator unit as set forth in claim 10 , wherein: the motor includes an encoder configured to measure an amount of reverse rotation of the rotating shaft of the motor, the reverse rotation occurring when an external force torque acts on an output shaft of the planetary reducer; the actuator unit further comprises a control circuit configured to control, in accordance with the amount of the reverse rotation measured by the encoder, the motor so as to absorb an impact torque acting on the output shaft of the planetary reducer; and the control circuit is further configured to control the motor so as to compensate a cogging torque generated at a timing of switching of magnetic poles of the first magnetic gear and the second magnetic gear engaged with each other. 12 . A link mechanism, comprising: a first link; a first joint connected to one end of the first link; a second joint connected to the other end of the first link; and a second link having one end connected to the second joint, each of the first joint and the second joint including an actuator unit recited in claim 10 . 13 . The link mechanism as set forth in claim 12 , further comprising: a control circuit configured to carry out (i) a damping control for the actuator unit of the first joint so that a force of a virtual damper acts on the other end of the second link and (ii) a compliance control for the actuator unit of the second joint so that a force of a virtual spring acts on the other end of the second link. 14 . A link mechanism, comprising: a first link; a first joint connected to one end of the first link; a second joint connected to the other end of the first link; a second link having one end connected to the second joint; a third link; a third joint connected to one end of the third link; a fourth joint connected to the other end of the third link; and a fourth link having one end connected to the fourth joint, each of the first joint, the second joint, the third joint and the fourth joint including an actuator unit recited in claim 10 , wherein the link mechanism further comprises a control circuit configured to execute, in order to grasp a target object with a small shock, (i) a first phase that carries out a damping control for the first joint and carries out a compliance control for the second joint, (ii) a second phase that carries out a position control for the third joint and causes the fourth joint to get closer to the target object, and (iii) a third phase that carries out a position control for the first joint and carries out a position control for the third joint so that a variation occurring in a virtual spring as a result of a compliance control for the fourth joint becomes constant, the first phase, the second phase, and the third phase being executed in this order. 15 . A link mechanism, comprising: a first link; a first joint connected to one end of the first link; a second joint connected to the other end of the first link; a second link having one end connected to the second joint; a third link; a third joint connected to one end of the third link; a fourth joint connected to the other end of the third link; and a fourth link having one end connected to the fourth joint, each of the first joint, the second joint, the third joint and the fourth joint including an actuator unit recited in claim 10 , wherein the link mechanism further comprises a control circuit configured to carry out, in order to grasp a target object with a small shock, a damping control for the first joint and a compliance control for the second joint as well as an angle control for the third joint and a compliance control for the fourth joint and then to control the first to fourth joints by a model constructed by a virtual spring and a virtual damper connected in parallel. 16 . An actuator unit, comprising: a motor; a first magnetic gear connected to a rotating shaft of the motor; a second magnetic gear configured to be magnetically engaged with the first magnetic gear; and a planetary reducer connected to a rotating shaft of the second magnetic gear, each of the first magnetic gear and the second magnetic gear being a magnetic gear recited in claim 5 . 17 . The actuator unit as set forth in claim 16 , wherein: the motor includes an encoder configured to measure an amount of reverse rotation of the rotating shaft o