Method for assembling rotor for use in IPM rotary machine

What is claimed is: 1. A method for assembling a rotor used in connection with an interior permanent magnet (IPM) rotary machine, the rotor having an axis of rotation and comprising a rotor yoke having bores and a plurality of permanent magnet segments disposed in the bores of the rotor yoke, each of the plurality of permanent magnet segments consisting of a plurality of magnet pieces, the method comprising subsequent order steps of: inserting and axially stacking the plurality of magnet pieces in each of the bores of the rotor yoke, each of the plurality of magnet pieces having a coercive force at a surface and an interior, and the coercive force near the surface of each of the plurality of magnet pieces being higher than that in the interior of each of the plurality of magnet pieces, with each of the plurality of magnet pieces being kept separate from each other prior to a step of fixedly securing the axially stacked plurality of magnet pieces to each other inside each of the bores of the rotor yoke to form each of said plurality of permanent magnet segments. 2. The method of claim 1 wherein provided that each of the plurality of magnet pieces has dimensions in axial, magnetization and width directions and each of said plurality of permanent magnet segments has a length in an axial direction, the axial dimension of each of the plurality of magnet pieces is no more than 1/2 of an axial length of each of the plurality of permanent magnet segments and longer than a shorter one of the dimensions of each of the plurality of magnet pieces in the magnetization and width directions. 3. The method of claim 1 wherein each of the plurality of magnet pieces is of sintered Nd base rare earth magnet. 4. The method of claim 1 wherein each of the plurality of magnet pieces is of sintered Nd base rare earth magnet and has a coercive force profile from a surface toward an interior, which is created by letting Dy or Tb diffuse from the surface toward the interior of each of the plurality of magnet pieces. 5. The method of claim 1 wherein each of the plurality of magnet pieces is of sintered Nd base rare earth magnet and has a coercive force profile from a surface toward an interior, which is created by letting Dy or Tb diffuse from the surface toward the interior of each of the plurality of magnet pieces mainly via grain boundaries. 6. The method of claim 1 wherein each of the plurality of magnet pieces have been magnetized in the step of inserting the plurality of magnet pieces in each bore of the rotor yoke for stacking the magnet pieces in the bore. 7. The method of claim 1 wherein each of the plurality of magnet pieces have not been magnetized in the step of inserting the plurality of magnet pieces in each of the bores of the rotor yoke for stacking the plurality of magnet pieces in the bore, the method further comprising the step of applying a magnetic field across the axially stacked plurality of magnet pieces in each of the bores from without the rotor for magnetizing the plurality of magnet pieces. 8. A method for assembling a rotor used in connection with an interior permanent magnet (IPM) rotary machine, the rotor having an axis of rotation and comprising a rotor yoke having bores and a plurality of permanent magnet segments disposed in the bores of the rotor yoke, each of the plurality of permanent magnet segments consisting of a plurality of magnet pieces, the method comprising subsequent order steps of: inserting and axially stacking the plurality of magnet pieces in each of the bores of the rotor yoke, each of the plurality of magnet pieces having heat resistance at a surface and an interior, and the heat resistance near the surface of each of the plurality of magnet pieces being higher than that in the interior of each of the plurality of magnet pieces, with each of the plurality of magnet pieces being kept separate from each other prior to a step of fixedly securing the axially stacked plurality of magnet pieces to each other inside each of the bores of the rotor yoke to form each of said plurality of permanent magnet segments. 9. The method of claim 8 wherein provided that each of the plurality of magnet pieces has dimensions in axial, magnetization and width directions and each of said plurality of permanent magnet segments has a length in an axial direction, the axial dimension of each of the plurality of magnet pieces is no more than 1/2 of an axial length of each of the plurality of permanent magnet segments and longer than a shorter one of the dimensions of each of the plurality of magnet pieces in the magnetization and width directions. 10. The method of claim 8 wherein each of the plurality of magnet pieces is of sintered Nd base rare earth magnet. 11. The method of claim 8 wherein each of the plurality of magnet pieces is of sintered Nd base rare earth magnet and has a heat resistance profile from a surface toward an interior, which is created by letting Dy or Tb diffuse from the surface toward the interior of each of the plurality of magnet pieces. 12. The method of claim 8 wherein each of the plurality of magnet pieces is of sintered Nd base rare earth magnet and has a heat resistance profile from a surface toward an interior, which is created by letting Dy or Tb diffuse from the surface toward the interior of each of the plurality of magnet pieces mainly via grain boundaries. 13. The method of claim 8 wherein each of the plurality of magnet pieces have been magnetized in the step of inserting the plurality of magnet pieces in each bore of the rotor yoke for stacking the magnet pieces in the bore. 14. The method of claim 8 wherein each of the plurality of magnet pieces have not been magnetized in the step of inserting the plurality of magnet pieces in each of the bores of the rotor yoke for stacking the plurality of magnet pieces in the bore, the method further comprising the step of applying a magnetic field across the axially stacked plurality of magnet pieces in each of the bores from without the rotor for magnetizing the plurality of magnet pieces.