Rotor unit, rotating electrical machine, and method for manufacturing rotor unit

The invention claimed is: 1. A rotor unit for a rotating electrical machine comprising: an annular rotor core including laminated steel sheets that are laminated in a vertical direction; a plurality of magnets arranged in a circumferential direction around the rotor core; and a holder made of resin that is arranged to hold the plurality of magnets; wherein the holder includes a plurality of partitioning portions that extends in the vertical direction along an outer peripheral surface of the rotor core, and a coupling portion that connects the plurality of partitioning portions; the rotor core and the holder are made of insert molded material so as to be fixed together; a portion of resin that defines the holder is present between the plurality of steel sheets that defines the rotor core in the outer peripheral surface of the rotor core; one of the plurality of magnets is press-fitted into a pair of the plurality of partitioning portions that are mutually adjacent; each of the plurality of partitioning portions includes: a columnar portion located between a pair of the plurality of magnets that are mutually adjacent; and a wall portion that partially covers a radial outside surface of the pair of the plurality of magnets; and an inner peripheral surface of the wall portion includes an inclined surface that gradually approaches the outer peripheral surface of the rotor core as the inclined surface extends downward in the vertical direction from an upper end of the rotor core in the vertical direction. 2. The rotor unit according to claim 1 , wherein an upper end of the wall portion in the vertical direction is located lower than an upper end of the rotor core in the vertical direction. 3. The rotor unit according to claim 1 , wherein an upper end of the wall portion in the vertical direction is located lower than an upper end of the columnar portion in the vertical direction. 4. The rotor unit according to claim 1 , wherein the coupling portion includes a bottom that faces a lower surface of the one of the plurality of magnets in the vertical direction; the bottom includes a recess located below two ends of the one of the plurality of magnets in the circumferential direction; and the recess is sealed by the one of the plurality of magnets. 5. The rotor unit according to claim 1 , wherein the rotor core includes a plurality of vertically extending groove portions in an outer peripheral surface thereof; the plurality of groove portions have a shape of which a dimension in a width direction decreases toward an outside in a radial direction; and the plurality of partitioning portions include engaging portions held within the plurality of groove portions. 6. A rotating electrical machine comprising: a stationary portion; and a rotating portion rotatably supported with respect to the stationary portion; wherein the rotating portion includes the rotor unit according to claim 1 , and a shaft inserted into the rotor core; and the stationary portion includes a bearing that rotatably supports the shaft, and an armature arranged radially outside the rotor unit. 7. The rotor unit according to claim 1 , wherein an inner surface of the wall portion is a cylindrical surface along the outer peripheral surface of the plurality of magnets which comes into contact with the outer peripheral surface of the magnet. 8. The rotor unit according to claim 1 , wherein a radial inside portion of the coupling portion comes into contact with a lower surface of the rotor core in the vertical direction. 9. A rotor unit for a rotating electrical machine, comprising: an annular rotor core including, a plurality of laminated steel sheets that are laminated in a vertical direction; a plurality of magnets arranged in a circumferential direction around the rotor core; and a holder made of resin that is arranged to hold the plurality of magnets; wherein the holder includes a plurality of partitioning portions that extends in the vertical direction along, an outer peripheral surface of the rotor core, and a coupling portion that connects the plurality of partitioning portions; the rotor core and the holder are made of insert molded material so as to be fixed together; a portion of resin that defines the holder is present between the plurality of steel sheets that defines the rotor core in the outer peripheral surface of the rotor core; one of the plurality of magnets is press-fitted into a pair of the plurality of partitioning portions that are mutually adjacent; and ends of the plurality of steel sheets are curved toward an upper side of the rotor core in the vertical direction in a vicinity of the outer peripheral surface of the rotor core. 10. A method of manufacturing a rotor unit for a rotating electrical machine including an annular rotor core including laminated steel sheets that are laminated in a vertical direction, a plurality of magnets arranged in a circumferential direction around the rotor core, and a holder made of resin that holds the plurality of magnets, the method comprising: a) arranging the rotor core inside a mold, and injecting resin in a fluid state into the mold to insert-mold the holder, wherein a plurality of partitioning portions that extends in the vertical direction along an outer peripheral surface of the rotor core, and a coupling portion that connects the partitioning portions are formed by insert molding; and b) a magnet of the plurality of magnets is press-fitted to a pair of the plurality of partitioning portions that are mutually adjacent after step a), wherein in step a), the plurality of partitioning portions is molded in a shape including a columnar portion located between ones of the plurality of magnets that are mutually adjacent, and a wall portion that partially covers radial outside surfaces of the ones of the plurality of magnets that are mutually adjacent; and an inclined surface that gradually approaches the outer peripheral surface of the rotor core extends downward in the vertical direction from an upper end of the rotor core in the vertical direction is molded on an inner peripheral surface of the wall portion. 11. The manufacturing method according to claim 10 , wherein an upper end of the wall portion in the vertical direction is molded at a position lower than an upper end of the rotor core in the vertical direction in step a). 12. The manufacturing method according to claim 10 , wherein an upper end of the wall portion in the vertical direction is molded at a position lower than an upper end of the columnar portion in the vertical direction in step a). 13. The manufacturing method according to claim 10 , wherein the coupling portion is molded in a shape including a bottom arranged at a circumferential position between the partitioning portions that are mutually adjacent, and a recess located at both ends of the bottom in a circumferential direction, in step a); and the magnet of the plurality of magnets seals the recess in step b).