JP4383802B2 - In-wheel motor - Google Patents

Description

  The present invention relates to an in-wheel motor, and more particularly to an in-wheel motor capable of efficiently cooling the motor.

  Patent Document 1 discloses an in-wheel motor in which a drive unit is housed in a wheel rim. The drive unit includes a case, a motor, and a planetary gear unit. The case houses the motor and the planetary gear unit. An oil reservoir chamber is provided in the lower part of the motor and the case, and oil (lubricating oil) is stored in the oil reservoir chamber.

  The motor rotor includes a rotor laminate and a hub. The hub supports the rotor laminate. The hub has an outer peripheral side flange that extends in the direction of the rotation axis of the rotor. This outer peripheral side collar part is located in the rotating shaft side rather than the outer peripheral surface of a rotor.

  The amount of oil varies between a position where the outer peripheral surface of the rotor is slightly immersed and a position where the outer peripheral side flange of the hub is immersed.

  When the rotor rotates, the rotor laminate and the outer flange side scoop up the oil. Then, the scooped-up oil travels along the rib provided in the case, lubricates the bearing and the planetary gear unit, and returns to the oil reservoir chamber.

As described above, in the conventional in-wheel motor, the oil accumulated in the lower part of the motor is swept up by the outer peripheral side flange of the rotor laminated plate and the hub supporting the rotor laminated plate to lubricate the bearing and the planetary gear unit. .
JP 2001-173762 A Japanese National Patent Publication No. 9-506236

  However, in the conventional in-wheel motor, the oil stored in the lower part of the motor is only circulated in the motor, and there is a problem that cooling of the oil (lubricating oil) is insufficient.

  Therefore, the present invention has been made to solve such a problem, and an object thereof is to provide an in-wheel motor capable of efficiently cooling lubricating oil.

According to this invention, an in-wheel motor is provided with a motor, a rotating shaft, a wheel, and an oil cooler. The rotating shaft is rotated by the output torque of the motor. The wheel is provided on one end side of the rotation shaft. The oil cooler is integrated with the wheel and cools the lubricating oil of the vehicle drive system. The oil cooler is built in the disk part of the wheel, and the oil cooler is a space part concentrically formed with the disk part.

Preferably, fins extending in the outer peripheral direction are provided in the space portion, and heat exchange is performed while oil moves in a space partitioned by the fins.
  Preferably, when the disk portion rotates, the oil in the space portion moves to promote oil circulation.

  Preferably, a paint having an emissivity higher than a predetermined value is applied to the outer surface of the disk portion.

  Preferably, the oil cooler receives / discharges the lubricating oil by rotation of the wheel.

  Preferably, the in-wheel motor further includes a check valve. The check valve is provided in an intake / exhaust hole for lubricating oil to the oil cooler.

  The in-wheel motor according to the present invention includes a wheel or a wheel hub integrated with an oil cooler. The lubricating oil is cooled by the oil cooler and then cools the motor.

  Therefore, according to the present invention, the lubricating oil can be cooled by the wheel or wheel hub in contact with the outside air. In particular, since the wheel or wheel hub receives an air flow according to the vehicle speed of the vehicle equipped with the in-wheel motor, it can efficiently release the heat conducted from the lubricating oil to the atmosphere, increasing the cooling efficiency of the lubricating oil. it can.

  Further, since the oil cooler is integrated with the wheel or the wheel hub, the size of the in-wheel motor capable of efficiently cooling the motor can be reduced.

  Furthermore, since the motor is cooled by the lubricating oil that has been efficiently cooled, the operating temperature range of the in-wheel motor can be expanded. As a result, an automobile equipped with the in-wheel motor according to the present invention can be operated even under severe load conditions.

  Embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

[Embodiment 1]
FIG. 1 is a schematic cross-sectional view and a plan view of an electric wheel provided with the in-wheel motor according to the first embodiment. 1A is a schematic cross-sectional view of the motor-driven wheel 100, and FIG. 1B is a plan view of the motor-driven wheel 100 viewed from the direction A shown in FIG.

  Referring to FIG. 1, an electric wheel 100 includes a wheel disk 10, a hub 20, a housing 30, a brake rotor 40, a brake caliper 50, a motor 60, bearings 71 to 76, a planetary gear 80, The shaft 110, the oil pump 120, oil passages 140, 150, 161 to 163, 181, 182, 190, a heat exchanging unit 170, a cover 180, and a tire 210 are provided.

  The electric wheel 100 is suspended from the frame of the automobile body by an upper arm and a lower arm (not shown).

  The wheel disc 10 has a substantially cup shape and includes a low portion 10A and a cylindrical portion 10B. The wheel disc 10 houses the hub 20, the housing 30, the brake rotor 40, the brake caliper 50, the motor 60, the bearings 71 to 76, the planetary gear 80, the shaft 110, the oil pump 120, and the oil passage 140. The wheel disc 10 is connected to the hub 20 by fastening the lower portion 10 </ b> A to the hub 20 with the screw 1. The hub 20 is spline fitted to the shaft 110. The hub 20 that is spline-fitted with the shaft 110 is rotatably supported by bearings 71 and 72.

  The brake rotor 40 is arranged such that the inner peripheral end is fixed to the hub 20 by screws 2 and 3 and the outer peripheral end passes through the brake caliper 50. The brake caliper 50 includes a brake piston 51 and brake pads 52 and 53. The brake pads 52 and 53 sandwich the outer peripheral end of the brake rotor 40. When brake oil is supplied from the opening 50A, the brake piston 51 moves to the right side of the page and pushes the brake pad 52 to the right side of the page. When the brake pad 52 is moved to the right side of the drawing by the brake piston 51, the brake pad 53 is moved to the left side of the drawing in response. As a result, the brake pads 52 and 53 sandwich the outer peripheral end of the brake rotor 40 and the electric wheel 100 is braked.

  A housing 30 is disposed on the left side of the hub 20 in the drawing. The housing 30 houses the motor 60. Motor 60 includes a stator core 61, a stator coil 62, and a rotor 63. The stator core 61 is fixed to the housing 30. The stator coil 62 is wound around the stator core 61. When motor 60 is a three-phase motor, stator coil 62 includes a U-phase coil, a V-phase coil, and a W-phase coil. A rotor 63 is disposed on the inner peripheral side of the stator core 61 and the stator coil 62.

  Planetary gear 80 includes a sun gear shaft 81, a sun gear 82, a pinion gear 83, a planetary carrier 84, and a ring gear 85. Sun gear shaft 81 is connected to rotor 63 of motor 60. The sun gear shaft 81 is rotatably supported by bearings 73 and 74. The sun gear 82 is connected to the sun gear shaft 81.

  The pinion gear 83 meshes with the sun gear 82 and is rotatably supported by bearings 75 and 76. The planetary carrier 84 is connected to the pinion gear 83 and is splined to the shaft 110. The ring gear 85 is fixed to the case 86.

  Since the shaft 110 is spline-fitted with the hub 20 and the planetary carrier 84 as described above, the shaft 110 is rotatably supported by the bearings 71, 72, and 76.

  The oil pump 120 is provided at one end of the shaft 110 (rotating shaft), that is, the end opposite to the wheel disk 10. The oil passage 121 is provided inside the pinion gear 83 of the planetary gear 80. The oil passage 140 has one end connected to the oil pump 120 and the other end inserted into the oil reservoir 130. Oil passages 150 and 190 are provided inside shaft 110. The oil passage 150 has one end connected to the oil pump 120 and the other end connected to the input port 151. The oil passage 190 has one end connected to the output port 152 and the other end closed. The oil passage 190 has an oil hole 191.

  The oil passages 161 to 163, 181, 182 and the heat exchange unit 170 are built in the lower portion 10 </ b> A of the wheel disc 10. The heat exchanging portion 170 has an uneven structure, and is formed concentrically with the wheel disc 10 at a predetermined radial position from the center O of the wheel disc 10. The cover 180 is fixed at a position facing the heat exchanging unit 170 by screws 4 and 5. Thereby, a space portion 170 </ b> A is formed between the heat exchange portion 170 and the cover 180.

  Oil passages 161 to 163 have one end connected to input port 151 and the other end connected to space portion 170A. Oil passages 181 and 182 have one end connected to space portion 170 </ b> A and the other end connected to output port 152.

  The oil pump 120 pumps up the oil accumulated in the oil reservoir 130 through the oil passage 140 and supplies the pumped oil to the oil passage 150. The oil passage 150 supplies oil from the oil pump 120 to the oil passages 161 to 163 via the input port 151. The oil passages 161 to 163 supply the oil supplied from the oil passage 150 to the space 170A.

  The heat exchange unit 170 performs heat exchange with the oil supplied to the space 170A to cool the oil. Oil passages 181 and 182 receive oil from space portion 170 </ b> A by the rotational force of wheel disc 10, and supply the received oil to oil passage 190 through output port 152.

  The oil supplied to the oil passage 190 is discharged from the oil hole 191 by the centrifugal force generated by the rotation of the shaft 110.

  The tire 210 is fixed to the outer edge of the cylindrical portion 10B of the wheel disc 10.

  When an alternating current is supplied to the stator coil 62 by a switching circuit (not shown) provided in the main body of the automobile on which the electric wheels 100 are mounted, the rotor 63 rotates and the motor 60 outputs a predetermined torque. The output torque of the motor 60 is transmitted to the planetary gear 80 via the sun gear shaft 81. The planetary gear 80 changes the output torque received from the sun gear shaft 81 by the sun gear 82 and the pinion gear 83, that is, changes speed and outputs it to the planetary carrier 84. The planetary carrier 84 transmits the output torque of the planetary gear 80 to the shaft 110, and the shaft 110 rotates the hub 20 and the wheel disc 10 at a predetermined number of rotations. Thereby, the electric wheel 100 rotates at a predetermined number of rotations.

  The oil pump 120 pumps up oil from the oil reservoir 130 via the oil passage 140 and supplies the pumped oil to the oil passage 150. The oil passage 150 supplies oil from the oil pump 120 to the oil passages 161 to 163 via the input port 151, and the oil passages 161 to 163 supply oil from the oil passage 150 to the space 170A.

  If it does so, the heat exchange part 170 will heat-exchange with the oil supplied to 170 A of space parts, and will cool oil. In this case, the oil supplied from the oil passages 161 to 163 to the space 170A is cooled by exchanging heat with the heat exchange unit 170 while moving the space 170A in the directions indicated by the arrows 6 and 7.

  The oil passages 181 and 182 supply the oil cooled by the heat exchange unit 170 to the oil passage 190 through the output port 152. The oil supplied to the oil passage 190 is discharged from the oil hole 191 by the centrifugal force generated by the rotation of the shaft 110.

  Oil discharged from the oil hole 191 is supplied to the bearings 71 to 76, the stator coil 62, the stator core 61, and the oil passage 121. The oil passage 121 supplies oil from the shaft 110 to the planetary gear 80.

  Thereby, the bearings 71 to 76 and the planetary gear 80 are lubricated. Further, the stator core 61 and the stator coil 62 are cooled.

  The oil supplied to the stator core 61, the stator coil 62, the bearings 71 to 76, and the planetary gear 80 returns to the oil reservoir 130 due to gravity drop.

  Thus, the oil stored in the oil reservoir 130 is supplied to the heat exchanging unit 170 built in the wheel disk 10 and cooled by the heat exchanging unit 170. The oil is cooled by the heat exchange unit 170 and then supplied to the stator core 61 and the stator coil 62 to cool the stator core 61 and the stator coil 62.

  Therefore, according to the present invention, the oil can be cooled by the wheel disc 10 in contact with the outside air. And since the flow velocity of the air according to the vehicle speed of the motor vehicle on which the electric wheel 100 is mounted can be obtained, the oil can be efficiently cooled. Moreover, since the stator core 61 and the stator coil 62 are cooled by the cooled oil, the motor 60 can be efficiently cooled.

  As a result, the operating temperature range of the motor 60 can be expanded, and an automobile equipped with the electric wheels 100 can be operated even under severe load conditions.

  Further, since the heat exchanging section 170 for cooling the oil is provided inside the wheel disk 10, the size of the in-wheel motor that can cool the motor 60 efficiently can be reduced.

  In the electric wheel 100, the wheel disk 10, the hub 20, the housing 30, the motor 60, the bearings 71 to 76, the planetary gear 80, the shaft 110, the oil pump 120, the oil reservoir 130, and the oil passages 140, 150, 161 to 163 are provided. , 181, 182, 190, the heat exchange unit 170 and the cover 180 constitute an “in-wheel motor” according to the first embodiment.

  Oil passages 161-163, 181, 182, heat exchanger 170 and cover 180 constitute an “oil cooler”.

  FIG. 2 is another schematic cross-sectional view and a plan view of the electric wheel provided with the in-wheel motor according to the first embodiment. 2A is a schematic cross-sectional view of the electric wheel 100A, and FIG. 2B is a plan view of the electric wheel 100A viewed from the direction A shown in FIG. 2A.

  Referring to FIG. 2, electric wheel 100A is obtained by replacing oil passages 161 to 163, 181, and 182 of electric wheel 100 with oil passages 161A and 162A, and heat exchanging portion 170 with groove 171. This is the same as the electric wheel 100.

  The groove 171 is provided so as to meander in the circumferential direction of the wheel disc 10 at a predetermined radial position from the center O of the wheel disc 10. The groove 171 is covered by the cover 180 and constitutes an oil passage 171A together with the cover 180.

  The oil passage 161A has one end connected to the input port 151 and the other end connected to the oil passage 171A. Oil passage 162A has one end connected to oil passage 171A and the other end connected to output port 152.

  The oil passage 161A receives oil from the oil passage 150 via the input port 151, and supplies the received oil to the oil passage 171A. The oil passage 171A moves the oil from the oil passage 161A in the direction of the arrow 8 and finally supplies it to the oil passage 162A.

  The oil is cooled by exchanging heat with the wheel disk 10 while moving in the oil passage 171A. Therefore, when the oil is supplied from the oil passage 161A to the oil passage 171A, the oil exchanges heat with the wheel disk 10, is cooled, and is supplied to the oil passage 162A.

  The oil passage 162A supplies oil from the oil passage 171A to the oil passage 190 via the output port 152.

  Others are as described in the electric wheel 100.

  Thus, in the electric wheel 100A, the wheel disc 10 includes the oil passage 171A meandering in the circumferential direction and the oil passages 161A and 162A connected to one end and the other end of the oil passage 171A, respectively. The oil can be reliably supplied to the oil passage 171A, and the oil cooled by the oil passage 171A can be reliably recovered and supplied to the oil passage 190.

  In the electric wheel 100A, the wheel disc 10, the hub 20, the housing 30, the motor 60, the bearings 71 to 76, the planetary gear 80, the shaft 110, the oil pump 120, the oil reservoir 130, and the oil passages 140, 150, 161A, 162A. , 171A (groove 171 and cover 180), 190 constitute an “in-wheel motor” according to the first embodiment.

  Oil passages 161A, 162A, and 171A (groove 171 and cover 180) constitute an “oil cooler”.

  FIG. 3 is still another schematic cross-sectional view and a plan view of the electric wheel provided with the in-wheel motor according to the first embodiment. 3A is a schematic cross-sectional view of the electric wheel 100B, and FIG. 3B is a plan view of the electric wheel 100B viewed from the A direction shown in FIG. 3A.

  Referring to FIG. 3, in electric wheel 100 </ b> B, oil passages 161 to 163, 181 and 182 of electric wheel 100 are replaced with oil passages 201 to 206, and heat exchange unit 170 is replaced with oil passages 211 to 216 and heat exchange units 217 to 217. The other parts are the same as those of the electric wheel 100.

  The oil passages 201 to 206, 211 to 216 and the heat exchange units 217 to 219 are built in the wheel disc 10. Oil passage 201 has one end connected to input port 151 and the other end connected to oil passage 211. The oil passage 202 has one end connected to the oil passage 212 and the other end connected to the output port 152.

  The oil passage 203 has one end connected to the input port 151 and the other end connected to the oil passage 213. The oil passage 204 has one end connected to the oil passage 214 and the other end connected to the output port 152. Oil passage 205 has one end connected to input port 151 and the other end connected to oil passage 215. Oil passage 206 has one end connected to oil passage 216 and the other end connected to output port 152.

  The oil passage 211 has one end connected to the oil passage 201 and the other end connected to the heat exchange unit 217. The oil passage 212 has one end connected to the heat exchange unit 217 and the other end connected to the oil passage 202.

  The oil passage 213 has one end connected to the oil passage 203 and the other end connected to the heat exchange unit 218. The oil passage 214 has one end connected to the heat exchange unit 218 and the other end connected to the oil passage 204.

  The oil passage 215 has one end connected to the oil passage 205 and the other end connected to the heat exchange unit 219. The oil passage 216 has one end connected to the heat exchange unit 219 and the other end connected to the oil passage 206.

  The heat exchange units 217 to 219 have an uneven structure and are covered with a cover 180.

  The heat exchange unit 217 performs heat exchange with the oil received via the oil passages 201 and 211 to cool the oil. The heat exchanging unit 217 supplies the cooled oil to the oil passages 212 and 202.

  The heat exchanging unit 218 performs heat exchange with the oil received through the oil passages 203 and 213 to cool the oil. Then, the heat exchange unit 218 supplies the cooled oil to the oil passages 214 and 204.

  The heat exchange unit 219 exchanges heat with the oil received through the oil passages 205 and 215 to cool the oil. The heat exchanging unit 219 supplies the cooled oil to the oil passages 216 and 206.

  Others are as described in the electric wheel 100.

  Thus, in the electric wheel 100 </ b> B, the plurality of heat exchange units 217 to 219 are provided inside the wheel disk 10. Then, the oil is individually supplied to each of the heat exchange units 217 to 219, cooled, and further collected. Therefore, the oil can be reliably supplied to the heat exchange units 217 to 219, and the oil cooled by the heat exchange units 217 to 219 can be reliably recovered and supplied to the oil passage 190.

  In the electric wheel 100B, the wheel disc 10, the hub 20, the housing 30, the motor 60, the bearings 71 to 76, the planetary gear 80, the shaft 110, the oil pump 120, the oil reservoir 130, and the oil passages 140, 150, 190, and 201. ˜206, 211 to 216, heat exchangers 217 to 219, and cover 180 constitute the “in-wheel motor” according to the first embodiment.

  The oil passages 201 to 210, 211 to 216, the heat exchange units 217 to 219, and the cover 180 constitute an “oil cooler”.

[Embodiment 2]
FIG. 4 is a schematic cross-sectional view and a plan view of an electric wheel provided with the in-wheel motor according to the second embodiment. 4A is a schematic cross-sectional view of the electric wheel 200, and FIG. 4B is a plan view of the electric wheel 200 viewed from the wheel disk 10. FIG. Referring to FIG. 4, electric wheel 200 includes oil passages 161 to 163, 181 and 182 of electric wheel 100 that are replaced with oil passages 221 to 225, heat exchange unit 170 is replaced with heat exchange unit 230, and cover 180 is covered. The other components are the same as those of the electric wheel 100.

  The oil passages 221 to 225 and the heat exchanging unit 230 are built in the lower part 10 </ b> A of the wheel disc 10. The heat exchanging portion 230 has an uneven structure, and is formed concentrically with the wheel disc 10 at a predetermined radial position from the center O of the wheel disc 10. The cover 240 is fixed at a position facing the heat exchanging unit 230 by screws 11 and 12. In particular, the cover 240 is fixed to the outer surface of the wheel disc 10. As a result, a space 230 </ b> A is formed between the heat exchange unit 230 and the cover 240.

  Oil passages 221 to 223 have one end connected to input port 151 and the other end connected to space portion 230A. Oil passages 224 and 225 have one end connected to space 230 </ b> A and the other end connected to output port 152.

  Oil passages 221 to 223 supply oil from oil passage 150 to space portion 230A. Then, the heat exchanging unit 230 performs heat exchange with the oil supplied to the space 230A to cool the oil. In this case, the oil supplied from the oil passages 221 to 223 to the space portion 230A is cooled by exchanging heat with the heat exchange portion 230 while moving the space portion 230A in the direction indicated by the arrows 13 and 14. In particular, the oil supplied to the space 230 </ b> A is efficiently cooled by the cover 240 provided on the outer surface of the wheel disk 10.

  The oil passages 224 and 225 supply the oil cooled by the heat exchange unit 230 to the oil passage 190 through the output port 152.

  As described above, in Embodiment 2, the cover 240 covering the heat exchanging unit 230 is provided on the outer surface of the wheel disk 10, so that the oil from the oil pump 120 is efficiently cooled and the cooled oil is used. The motor 60 can be cooled.

  As a result, the operating temperature range of the motor 60 can be expanded, and an automobile equipped with the electric wheels 100 can be operated even under severe load conditions.

  Further, the heat exchanging unit 230 for cooling the oil is provided inside the wheel disk 10 and radiates heat to the air in contact with the outer surface of the wheel disk 10, so that the physique of the in-wheel motor capable of efficiently cooling the motor 60 is increased. Can be reduced.

  In the electric wheel 200, the wheel disk 10, the hub 20, the housing 30, the motor 60, the bearings 71 to 76, the planetary gear 80, the shaft 110, the oil pump 120, the oil reservoir 130, the oil passages 140, 150, 190, and 221. ˜225, heat exchanging unit 230 and cover 240 constitute an “in-wheel motor” according to the second embodiment.

  The oil passages 221 to 225, the heat exchanging unit 230, and the cover 240 constitute an “oil cooler”.

  Others are the same as in the first embodiment.

[Embodiment 3]
FIG. 5 is a schematic cross-sectional view and a plan view of an electric wheel provided with the in-wheel motor according to the third embodiment. 5A is a schematic cross-sectional view of the electric wheel 300, and FIG. 5B is a plan view of the electric wheel 300 viewed from the wheel disk 10 side.

  Referring to FIG. 5, in the electric wheel 300, the oil passages 161 to 163, 181 and 182 of the electric wheel 100 are replaced with the oil passages 231 to 239 and 241, the heat exchanging unit 170 is replaced with the heat exchanging unit 250, and the input port 151 is replaced with the input port 153, the output port 152 is replaced with the output port 154, fins 242 to 246 are added, and the rest is the same as the electric wheel 100.

  In electric wheel 300, oil passage 150 has the other end connected to input port 153, and oil passage 190 has one end connected to output port 154. Further, in the electric wheel 300, the cover 180 is fixed to the wheel disk 10 so as to face the heat exchange unit 250. As a result, a space 250 </ b> A is formed between the cover 180 and the heat exchange unit 250.

  Oil passages 231, 233, 235, 237, and 239 have one end connected to input port 153 and the other end connected to space 250 </ b> A. Oil passages 232, 234, 236, 238, and 241 have one end connected to space 250 </ b> A and the other end connected to output port 154.

  The fin 242 is provided in the space portion 250A so that one end thereof is fixed to the inner peripheral wall 251 of the space portion 250A between the oil passage 232 and the oil passage 233. The fin 243 is provided in the space portion 250A so that one end is fixed to the inner peripheral wall 251 of the space portion 250A between the oil passage 234 and the oil passage 235. The fin 244 is provided in the space portion 250A so that one end thereof is fixed to the inner peripheral wall 251 of the space portion 250A between the oil passage 236 and the oil passage 237.

  The fin 245 is provided in the space 250A so that one end thereof is fixed to the inner peripheral wall 251 of the space 250A between the oil passage 238 and the oil passage 239. The fin 246 is provided in the space 250A so that one end thereof is fixed to the inner peripheral wall 251 of the space 250A between the oil passage 241 and the oil passage 231.

  The oil passages 231, 233, 235, 237, and 239 supply oil supplied from the oil passage 150 via the input port 153 to the space 250 </ b> A. The oil passages 232, 234, 236, 238, and 241 supply oil from the space portion 250 A to the oil passage 190 through the output port 154.

  When the wheel disc 10 rotates in the direction indicated by the arrow 15, the fins 242 to 246 guide the oil in the space 250 </ b> A to the oil passages 232, 234, 236, 238 and 241, respectively.

  More specifically, the fin 242 guides the oil supplied from the oil passage 231 to the space 250A to the oil passage 232, and the fin 243 supplies the oil supplied from the oil passage 233 to the space 250A to the oil passage 234. The fins 244 guide the oil supplied from the oil passage 235 to the space 250 </ b> A to the oil passage 236.

  In addition, the fin 245 guides oil supplied from the oil passage 237 to the space 250A to the oil passage 238, and the fin 246 guides oil supplied from the oil passage 239 to the space 250A to the oil passage 241.

  When an alternating current is supplied to the stator coil 62 by a switching circuit (not shown), the rotor 63 rotates and the motor 60 outputs a predetermined torque. The output torque of the motor 60 is transmitted to the shaft 110 by the mechanism described above, and the shaft 110 rotates the hub 20 and the wheel disc 10 at a predetermined rotational speed. Thereby, the electric wheel 100 rotates at a predetermined number of rotations.

  On the other hand, the oil pump 120 pumps oil from the oil reservoir 130 through the oil passage 140 and supplies the pumped oil to the oil passage 150. The oil passage 150 supplies oil from the oil pump 120 to the oil passages 231, 233, 235, 237, 239 via the input port 153, and the oil passages 231, 233, 235, 237, 239 are oil passages The oil from 150 is supplied to the space 250A.

  If it does so, the heat exchange part 250 will perform heat exchange with the oil supplied to 250 A of space parts, and will cool oil. In this case, the oil supplied from the oil passages 231, 233, 235, 237, and 239 to the space 250 A moves through the space 250 A in the directions indicated by the arrows 16 A, 16 B, 16 C, 16 D, and 16 E, respectively. Heat exchange is performed with the unit 250 to be cooled.

  The fins 242 to 246 guide the oil cooled by the heat exchange unit 250 to the oil passages 232, 234, 236, 238, and 241 respectively, and the oil passages 232, 234, 236, 238, and 241 Is supplied to the oil passage 190 via the output port 154.

  Thereafter, the oil lubricates the bearings 71 to 76 and the planetary gear 80 and cools the stator core 61 and the stator coil 62 by the mechanism described above. Then, the oil returns to the oil reservoir 130.

  Thus, the oil moves between the two adjacent fins in the space 250A and is cooled by the heat exchange unit 250, so that the oil can be reliably supplied to the space 250A and is cooled by the space 250A. The collected oil can be reliably recovered and supplied to the oil passage 190. Further, the oil is promoted to circulate through the oil passages 231, 233, 235, 237, 239, the space 250 A and the oil passages 232, 234, 236, 238, and 241 by the rotation of the wheel disk 10, so that the oil pump 120 The discharge pressure of the oil pump 120 can be reduced, and the size of the oil pump 120 can be reduced.

  In the electric wheel 300, the wheel disk 10, the hub 20, the housing 30, the motor 60, the bearings 71 to 76, the planetary gear 80, the shaft 110, the oil pump 120, the oil reservoir 130, the oil passages 140, 150, 190, and 231. 239, 241, fins 242 to 246, heat exchanging unit 250 and cover 180 constitute an “in-wheel motor” according to the third embodiment.

  The oil passages 231 to 239 and 241, the fins 242 to 246, the heat exchange unit 250, and the cover 180 constitute an “oil cooler”.

  FIG. 6 is another schematic cross-sectional view and plan view of an electric wheel provided with the in-wheel motor according to the third embodiment. 6A is a schematic cross-sectional view of the electric wheel 300A, and FIG. 6B is a plan view of the electric wheel 300A viewed from the wheel disk 10 side.

  Referring to FIG. 6, electric wheel 300 </ b> A is obtained by deleting oil pump 120 of electric wheel 300, and the other parts are the same as electric wheel 300. In electric wheel 300A, oil passage 140 is connected to oil passage 150.

  As described above, the oil is promoted to circulate to the oil passages 231, 233, 235, 237, 239, the space 250 A and the oil passages 232, 234, 236, 238, and 241 by the rotation of the wheel disk 10. The oil stored in the oil reservoir 130 can easily move through the oil passages 140 and 150. Therefore, even if the oil pump 120 is not provided, the oil stored in the oil reservoir 130 remains in the oil passage 140, the oil passage 150, the input port 153, the oil passages 231, 233, 235, 237, 239, the space 250A, the oil passage. 232, 234, 236, 238, 241, the output port 154, and the oil passage 190 are circulated.

  Therefore, the motor wheel 300A can be made smaller than the motor wheel 300, and the cost can be reduced.

  In the electric wheel 300A, the wheel disc 10, hub 20, housing 30, motor 60, bearings 71 to 76, planetary gear 80, shaft 110, oil reservoir 130, oil passages 140, 150, 190, 231 to 239, 241 , Fins 242-246, heat exchanging section 250 and cover 180 constitute an “in-wheel motor” according to the third embodiment.

  The oil passages 231 to 239 and 241, the fins 242 to 246, the heat exchange unit 250, and the cover 180 constitute an “oil cooler”.

  Others are the same as in the first embodiment.

[Embodiment 4]
FIG. 7 is a schematic sectional view of an electric wheel provided with an in-wheel motor according to the fourth embodiment. Referring to FIG. 7, motor-driven wheel 400 is the same as motor-driven wheel 100 except that input port 151 of motor-driven wheel 100 is replaced with check valve 155 and output port 152 is replaced with check valve 156. .

  The check valve 155 is disposed between the oil passage 150 and the oil passage 161. The check valve 156 is disposed between the oil passage 181 and the oil passage 190.

  FIG. 8 is an enlarged view of the vicinity of the check valves 155 and 156 shown in FIG. Referring to FIG. 8, check valves 155 and 156 are provided in shaft 110. The check valve 155 includes a ball 155A and a spring 155B. The ball 155A is disposed on the oil passage 150 side. The spring 155B pushes the ball 155A in the direction of the arrow 17.

  The check valve 156 includes a ball 156A and a spring 156B. The ball 156A is disposed on the oil passage 181 side. The spring 156B pushes the ball 156A in the direction of the arrow 17.

  When the oil pump 120 is activated and the oil passage 150 supplies oil to the check valve 155, the ball 155A is pushed in the direction opposite to the arrow 17 by the oil. The oil passage 150 communicates with the oil passage 161, and oil is supplied from the oil passage 150 to the oil passage 161 via the check valve 155.

  When oil passage 181 supplies oil to check valve 156, ball 156A is pushed in the direction opposite to arrow 17 by the oil, and oil passage 181 communicates with oil passage 190. Then, the oil is supplied from the oil passage 181 to the oil passage 190 via the check valve 156.

  As described above, when the oil pump 120 is operated, oil is supplied from the oil passage 150 to the oil passage 161 and supplied from the oil passage 181 to the oil passage 190. Thereby, oil circulates by the mechanism mentioned above.

  On the other hand, when the oil pump 120 stops, the discharge pressure disappears, so the springs 155B and 156B push the balls 155A and 156A in the direction of the arrow 17, respectively, and the oil passage 150 is blocked from the oil passage 161 by the check valve 155. The oil passage 190 is blocked from the oil passage 181 by the check valve 156.

  Therefore, it is possible to prevent the oil accumulated in the oil passages 150 and 190 from leaking even when the wheel disk 10 is detached from the shaft 110. As a result, oil leakage at the time of replacement of the brake pads 52 and 53, the tire 210, etc. can be prevented, and the maintenance efficiency of the vehicle can be improved.

  FIG. 9 is another enlarged view in the vicinity of the check valves 155 and 156 shown in FIG. Referring to FIG. 9, check valves 155 and 156 are provided inside wheel disc 10. Therefore, when the wheel disc 10 is detached from the shaft 110, it is possible to prevent the oil accumulated in the oil passages 161 to 163, 181, 182 and the space 170A of the wheel disc 10 from leaking. Others are the same as the description in FIG.

  FIG. 10 is another enlarged view of the vicinity of the check valves 155 and 156 shown in FIG. Referring to FIG. 10, check valves 155 and 156 are provided inside shaft 110, and check valves 157 and 158 are provided inside wheel disc 10. The check valve 155 is connected to the check valve 157, and the check valve 156 is connected to the check valve 158.

  Check valve 157 includes a ball 157A and a spring 157B. The ball 157A is disposed on the check valve 155 side. The spring 157B pushes the ball 157A in the direction of the arrow 17. Check valve 158 includes a ball 158A and a spring 158B. The ball 158A is disposed on the side opposite to the check valve 156. The spring 158B pushes the ball 158A in the direction of the arrow 17.

  When the oil pump 120 is activated and the oil passage 150 supplies oil to the check valve 155, the ball 155A is pushed in the direction opposite to the arrow 17 by the oil. Then, the oil is supplied to the check valve 157 via the check valve 155 and pushes the ball 157A in the direction opposite to the arrow 17. As a result, the oil passage 150 communicates with the oil passage 161, and oil is supplied from the oil passage 150 to the oil passage 161 via the check valves 155 and 157.

  Further, when the oil passage 181 supplies oil to the check valve 158, the ball 158A is pushed in the opposite direction to the arrow 17 by the oil, and the oil pushes the ball 156A of the check valve 156 in the opposite direction to the arrow 17. As a result, the oil passage 181 communicates with the oil passage 190. Then, the oil is supplied from the oil passage 181 to the oil passage 190 via the check valves 158 and 156.

  On the other hand, when the oil pump 120 is stopped, the springs 155B, 156B, 157B, 158B push the balls 155A, 156A, 157A, 158A in the direction of the arrow 17, respectively, and the oil passage 150 is moved by the check valves 155, 157. 161 and the oil passage 190 is cut off from the oil passage 181 by the check valves 156 and 158.

  Therefore, even if the wheel disk 10 is detached from the shaft 110, the oil accumulated in the oil passages 150 and 190 and the oil accumulated in the wheel disk 10 can be prevented from leaking. As a result, oil leakage at the time of replacement of the brake pads 52 and 53, the tire 210, etc. can be prevented, and the maintenance efficiency of the vehicle can be improved.

  The electric wheel according to the fourth embodiment may be an electric wheel using check valves 155 and 156 in the manner shown in FIG. 8 or 9 in the above-described electric wheels 100A, 100B, 200, 300, and 300A. 100A, 100B, 200, 300, 300A may be an electric wheel using check valves 155 to 158 in the manner shown in FIG.

  In the electric wheel 400, the wheel disk 10, the hub 20, the housing 30, the motor 60, the bearings 71 to 76, the planetary gear 80, the shaft 110, the oil pump 120, the oil reservoir 130, the oil passages 140, 150, 161 to 163. , 181, 182, 190, check valves 155 to 158, heat exchanger 170 and cover 180 constitute an “in-wheel motor” according to the fourth embodiment.

  Oil passages 161-163, 181, 182, heat exchanger 170 and cover 180 constitute an “oil cooler”.

  Others are the same as in the first embodiment.

[Embodiment 5]
FIG. 11 is a schematic cross-sectional view of an electric wheel provided with the in-wheel motor according to the fifth embodiment. Referring to FIG. 11, electric wheel 500 deletes oil passages 161-163, 181 and 182 of electric wheel 100, replaces wheel disk 10 with wheel disk 260, replaces hub 20 with hub 270 and hub cover 280, The heat exchanging unit 170 is replaced with a heat exchanging unit 290, and the rest is the same as that of the electric wheel 100.

  The wheel disc 260 has a substantially cup shape and includes a low portion 260A and a cylindrical portion 260B. The hub 270 is provided on the inner peripheral side of the wheel disc 260. The wheel disc 260 and the hub 270 accommodate the hub cover 280, the housing 30, the brake rotor 40, the brake caliper 50, the motor 60, the bearings 71 to 76, the planetary gear 80, the shaft 110, the oil pump 120, and the oil passage 140.

  The wheel disc 260 is fixed to the hub 270 by fastening the lower portion 260 </ b> A to the hub 270 with the screw 1. The inner periphery of the brake rotor 40 is fixed to the hub 270 by screws 2 and 3. The hub cover 280 is provided inside the hub 270 (on the motor 60 side). The hub 270 is fixed to the hub cover 280 by screws 18 and 19. Hub cover 280 is spline-fitted to shaft 110. The hub cover 280 that is spline-fitted with the shaft 110 is rotatably supported by the bearings 71 and 72.

  As a result, the wheel disc 260, the hub 270, and the hub cover 280 rotate as the shaft 110 rotates.

  The hub 270 includes a heat exchange unit 290. The outer surface 271 of the hub 270 protrudes outside the outer surface 261 of the wheel disc 260 (on the side opposite to the motor 60 side).

  The heat exchange part 290 has a concavo-convex structure. By fixing the hub cover 280 to the hub 270 with the screws 18 and 19, a space 290A is formed between the hub cover 280 and the heat exchange unit 290. The space portion 290 </ b> A has a substantially donut shape and is provided concentrically with the hub 270. The space portion 290 </ b> A is connected to the oil passage 150 via the input port 151 and is connected to the oil passage 190 via the output port 152.

  When the oil is supplied to the space 290A, the heat exchange unit 290 performs heat exchange with the oil and cools the oil. Then, the heat conducted to the hub 270 via the heat exchange unit 290 is released from the outer surface 271 of the hub 270 to the atmosphere.

  When an alternating current is supplied to the stator coil 62 by a switching circuit (not shown), the motor 60 outputs a predetermined output torque. The output torque of the motor 60 is transmitted to the shaft 110 by the mechanism described above, and the shaft 110 rotates at a predetermined number of rotations.

  Then, the rotation of shaft 110 is transmitted to hub cover 280, hub 270, and wheel disc 260, and electric wheel 500 rotates at a predetermined number of rotations.

  On the other hand, the oil pump 120 pumps oil from the oil reservoir 130 via the oil passage 140 and supplies the pumped oil to the oil passage 150. The oil passage 150 supplies oil from the oil pump 120 to the space portion 290 </ b> A via the input port 151.

  When the oil is supplied to the space 290A, the heat exchange unit 290 takes heat from the oil and cools the oil. Then, the heat conducted to the hub 270 through the heat exchange unit 290 is released from the outer surface 271 to the atmosphere.

  The oil cooled by the heat exchange unit 290 is supplied to the oil passage 190 through the output port 152. Thereafter, the oil lubricates the bearings 71 to 76 and the planetary gear 80 and cools the stator core 61 and the stator coil 62 by the mechanism described above.

  Thus, in the electric wheel 500, the oil is cooled by the heat exchanging part 290 built in the hub 270 provided separately from the wheel disk 260, and the bearings 71 to 76 and the planetary gear 80 are moved by the cooled oil. Lubricate and cool the stator core 61 and the stator coil 62.

  Therefore, the oil can be cooled by the hub 270 having the outer surface 271 protruding outside the outer surface 261 of the wheel disc 260. As a result, the oil can be efficiently cooled. In particular, the outer surface 271 of the hub 270 that protrudes to the outside is always in contact with the outside air, and the air flow rate corresponding to the vehicle speed can be increased, so that the oil cooling efficiency can be increased.

  Further, since the oil is cooled by the hub 270 provided separately from the wheel disc 260, oil leakage can be eliminated during tire replacement.

  In the electric wheel 500, the housing 30, the motor 60, the bearings 71 to 76, the planetary gear 80, the shaft 110, the oil pump 120, the oil reservoir 130, the oil passages 140, 150, 190, the wheel disc 260, the hub 270, and the hub cover. 280 and heat exchange unit 290 constitute an “in-wheel motor” according to the fifth embodiment.

  The hub 270, the hub cover 280, and the heat exchange unit 290 constitute an “oil cooler”.

  Others are the same as in the first embodiment.

[Embodiment 6]
FIG. 12 is a schematic cross-sectional view of an electric wheel provided with the in-wheel motor according to the sixth embodiment. Referring to FIG. 12, an electric wheel 600 is obtained by adding a paint 310 to the electric wheel 100, and the rest is the same as the electric wheel 100.

  The paint 310 is made of a far-infrared ceramic paint and is applied to the outer surface 10 </ b> C of the lower portion 10 </ b> A of the wheel disk 10. The paint 310 does not necessarily have to be applied to the entire surface of the lower portion 10 </ b> A of the wheel disk 10, and it is sufficient that the paint 310 is applied to at least a portion of the outer surface facing the heat exchange unit 170.

  The paint 310 makes the emissivity of the heat taken away from the oil by the heat exchange unit 170 into the atmosphere higher than a predetermined value. That is, the paint 310 increases the amount of heat released by radiation from the wheel disk 10 into the atmosphere. The predetermined value is the emissivity of the wheel disc 10 when the paint 310 is not applied.

  Therefore, the heat conducted to the wheel disk 10 through the heat exchange unit 170 is efficiently radiated to the atmosphere by the paint 310. As a result, the cooling efficiency of the oil supplied to the space 170A can be further improved.

  Further, this improvement in cooling efficiency is realized both when the automobile equipped with the electric wheels 600 is running and when it is stopped.

  The electric wheel according to the sixth embodiment is an electric wheel in which paint 310 is applied to the outer surfaces of the wheel disk 10 of the electric wheel 100A, 100B, 200, 300, 300A, 400 and the wheel disk 260 of the electric wheel 500 described above. Also good.

  In the electric wheel 600, the wheel disc 10, the hub 20, the housing 30, the motor 60, the bearings 71 to 76, the planetary gear 80, the shaft 110, the oil pump 120, the oil reservoir 130, and the oil passages 140, 150, 161 to 163 are provided. , 181, 182, 190, the heat exchange unit 170, the cover 180, and the paint 310 constitute an “in-wheel motor” according to the sixth embodiment.

  Oil passages 161-163, 181, 182, heat exchanger 170, cover 180, and paint 310 constitute an “oil cooler”.

  Others are the same as in the first embodiment.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and is intended to include meanings equivalent to the scope of claims for patent and all modifications within the scope.

  The present invention is applied to an in-wheel motor with good cooling efficiency.

It is the schematic sectional drawing and top view of an electric wheel provided with the in-wheel motor by Embodiment 1. It is the other schematic sectional drawing and top view of an electric wheel provided with the in-wheel motor by Embodiment 1. It is another schematic sectional drawing and top view of an electric wheel provided with the in-wheel motor by Embodiment 1. It is the schematic sectional drawing and top view of an electric wheel provided with the in-wheel motor by Embodiment 2. It is the schematic sectional drawing and top view of an electric wheel provided with the in-wheel motor by Embodiment 3. It is the other schematic sectional drawing and top view of an electrically-driven wheel provided with the in-wheel motor by Embodiment 3. 6 is a schematic cross-sectional view of an electric wheel provided with an in-wheel motor according to Embodiment 4. FIG. It is an enlarged view of the vicinity of the check valve shown in FIG. FIG. 8 is another enlarged view of the vicinity of the check valve shown in FIG. 7. FIG. 10 is still another enlarged view of the vicinity of the check valve shown in FIG. 7. FIG. 10 is a schematic cross-sectional view of an electric wheel provided with an in-wheel motor according to a fifth embodiment. FIG. 10 is a schematic sectional view of an electric wheel provided with an in-wheel motor according to a sixth embodiment.

Explanation of symbols

  1-5, 18, 19 Screw, 6-8, 13-15, 16A, 16B, 16C, 16D, 16E, 17 Arrow, 10,260 Wheel disc, 10A, 260A Low part, 10B, 260B Cylindrical part, 10C , 261,271 outer surface, 20,270 hub, 30 housing, 40 brake rotor, 50 brake caliper, 50A opening, 51 brake piston, 52, 53 brake pad, 60 motor, 61 stator core, 62 stator coil, 63 rotor, 71-76 bearing, 80 planetary gear, 81 sun gear shaft, 82 sun gear, 83 pinion gear, 84 planetary carrier, 85 ring gear, 86 case, 100, 100A, 100B, 200, 300, 300A, 400, 500, 600 , 11 Shaft, 120 oil pump, 121,140,150,161-163,161A, 162A, 171A, 181,182,201-206, 211-216,221-225,231-239,241 oil passage, 130 oil reservoir, 151, 153 Input port, 152, 154 Output port, 170, 217-219, 230, 250, 290 Heat exchanger, 155-158 Check valve, 155A, 156A, 157A, 158A Ball, 155B, 156B, 157B, 158B Spring 170A, 230A, 250A, 290A space, 171 groove, 180, 240 cover, 191 oil hole, 210 tire, 242-246 fin, 280 hub cover, 310 paint.

Claims (6)

A motor,
A rotating shaft that rotates by the output torque of the motor;
A wheel provided on one end side of the rotating shaft;
An oil cooler that is integrated with the wheel and cools the lubricating oil of the vehicle drive system,
The oil cooler is built in the disc part of the wheel,
The oil cooler is an in-wheel motor that is a space portion concentrically formed with the disk portion.   The in-wheel motor according to claim 1, wherein fins extending in an outer peripheral direction are provided in the space portion, and heat exchange is performed while oil moves in a space partitioned by the fins.   The in-wheel motor according to claim 2, wherein the oil in the space portion is moved by the rotation of the disk portion to promote oil circulation.   The in-wheel motor according to claim 1, wherein a paint having an emissivity higher than a predetermined value is applied to an outer surface of the disk portion.   The in-wheel motor according to claim 1, wherein the oil cooler receives / discharges the lubricating oil by rotation of the wheel.   The in-wheel motor according to claim 1, further comprising a check valve provided in an intake / exhaust hole of the lubricating oil to the oil cooler.

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