TH29623B - Hydrodynamic bearing unit - Google Patents

Abstract

DC60 (28/09/44) Surface perpendicularity at both ends of the surrounding protrusions relative to the circumference. The outside of the spindle part of the spindle assembly is set to 0.001 mm or less respectively. and the smoothness of the surfaces at both ends, the surfaces of the surrounding overhangs are obtained The designation is set equal to 0.001 mm or less respectively. the perpendicularity of the surface The tip of the bearing assembly relative to the inner circumference of the bearing assembly is set to 0.002 mm or less. and the flatness is set to 0.0015 mm or less. the smoothness of the inner surface of the bottom part of the housing is set to 0.002 millimeters or less. Perpendicularity of the surface at both ends of the surface of the surrounding protrusion relative to the circumference The outside of the spindle part of the spindle assembly is set to 0.001 mm or less respectively. and the smoothness of the surfaces at both ends of the surface of the surrounding protruding edges was obtained The designation is set equal to 0.001 mm or less respectively. the perpendicularity of the surface The tip of the bearing assembly relative to the inner circumference of the bearing assembly is set to 0.002 mm or less. and the flatness is set to 0.0015 mm or less. the smoothness of the inner surface of the bottom part of the housing is set to 0.002 millimeters or less.

Claims (9)

1. Hydrodynamic bearing series consisting of A case with a bottom section; A bearing assembly that is fixed to the inner circumference of the housing. Clamping piece, which has a core inserted through the heel around the inner ring of the bearing assembly and the surrounding protrusion. The radial part of the bearing, which is provided between the inner circumference of the piece, exceeds the bearing and The outer circumference of the axial part of the assembly for supporting the axial assembly in a radial direction in a state where dynamic pressure does not occur in contact with the radial and bearing distances. The axial component is arranged sequentially between the end surfaces of the peripheral protrusion of the axial assembly and the end surfaces of the bearing assembly or the inner surface of the periphery of the axial assembly. A housing for supporting axial assemblies in an axial direction in a state where dynamic pressure does not occur in contact with axial bearing distance. Where the size condition between the inner surface and the outer surface of the case is 0.005 mm or less. 2. Dynamic pressure bearing set according to claim 1, where the orthogonal surface at both ends of the peripheral protrusion relative to the outer circumference of the axial garden of the axial assembly is Equal to 0.001 mm or less, respectively. And the smoothness of the surfaces at both ends of the surface of the periphery is 0.001 mm or less. 3. Hydrodynamic bearing assembly according to claim 1, where the square of the surface at the end of the bearing assembly is opposite to the end surface of one of the two opposite surfaces. Surrounding edge By using axial bearing spacing relative to the inner circumference of the bearing assembly, it is 0.002 mm or less. And that smoothness would be 0.0015 mm or less. 4. Dynamic bearing set according to claim 2, where the orthogonal surface at the end of the bearing assembly is opposite to the end surface, one of the two protruding surfaces. The circumference, based on the axial bearing clearance relative to the inner circumference of the bearing assembly, is 0.002 mm or less. And that smoothness is going to be 0.0015 mm or less. 5. Hydrodynamic bearing set in accordance with any of Clause 1 to 4. Where the flatness of the inner surface of the casing's bottom is 0.002 mm or less. 6.The hydrodynamic bearing set includes A case with a bottom section A bearing gasket that is fixed to the inner circumference of the housing. Axial assembly, which has an axial part inserted into a surface along the inner circumference. The bearing assembly and the axial plate provided on the axial section. The radial bearing part is provided between the surface along the inner circumference of the bearing assembly and the outer circumference surface of the axial part of the axial assembly. As for supporting the axial part in the radial direction in the non-contact state. With the action of the fluid dynamics pressure arising in a radial distance; And the axial bearing assembly, which is provided respectively, between the end surfaces of the said axial plates of the axial assembly and the lower end surfaces of the said bearing assemblies or areas. On the bottom surface of the case for supporting the said axial plate in the direction of Nagan in a state that does not come into contact with the action of fluid dynamics pressure arising at axial bearing distance. Where the surface hardness of the surface along the outer circumference of the axes is greater than the surface hardness of the surface along the inner circumference of the bearing assembly. The surface hardness of the two patterned surfaces of the axial plates is greater than the surface hardness of the substrate at the bottom end of the bearing assembly and the bottom surface of the bearing surface. Such a housing The surface roughness of the surface along the outer circumference of the axial portion is less than the surface roughness of the surface along the inner circumference of the bearing assembly. The surface roughness of the surface of such axial plates is less than the surface roughness of the surface at the bottom end of the bearing assembly and the bottom surface of such housing and floor. The surface along the peripheral emphasis of the axial portion has the characteristics of the surface in which the small protrusions that make up the surface roughness are smoothed. 7. Hydrodynamic bearing set according to the claim Where the angle of the median delta q of the surface along the outer circumference of the axis is 2.0 or less. 8. Hydrodynamic bearing set according to claim 6, where the surfaces at both ends of such axial plates have the characteristics of the surface where the small protrusions that make up the The roughness of the surface has been smoothed. 9. Hydrodynamic bearing set according to claim 7, where the surfaces at both ends of the axial plates have the characteristics of the surface where the small protrusions that make up the The roughness of the surface is smoothed 1 0. The hydrodynamic push bearing set according to claim 8, where the angle of inclination is the mean delta q of the surface at both ends of the plate. These axes are equal to 2.0 or less. 1 1. Hydrodynamic pressure bearing set in claim 9, where the angle of inclination is the mean delta q of the surfaces at both ends. The surface of such axial plates is 2.0 or less. 1 2. Any set of hydrodynamic bearings in Clause 6 to 11. Where the arithmetic mean deviation Ra of the surface along the outer circumference of the axial segment is 0.04 μm or less.1 3. Which of the hydrodynamic bearing set according to claim 6 to 11? One Where the arithmetic mean deviation Ra of the surfaces at both ends of the axial plates is 0.04 μm or less 1 4. Hydrodynamic bearing according to claim 12, where The arithmetic mean deviation Ra of the surfaces at both ends of such axial plates is equal to 0.04 μm Or less