TH49527A - Methods for manufacturing hydrodynamic bearing devices - Google Patents

Abstract

The DC60 (30/06/53) axial assembly 2 has been rotated with a 21 drive plate while supporting the surface. Along the outer circumference of the axial part 2a with cladding 20, a rotary abrasive wheel 22 is then applied to the end surface of the axial plate 2b of the rotating axial component 2, which is the abrasive. The end of the axial plate 2b. The axial assembly 2 is rotated with the drive plate 21 while supporting the surface. Along the outer circumference of the axial part 2a with cladding 20, a rotary abrasive wheel 22 is then applied to the end surface of the axial plate 2b of the rotating axial component 2, which is the abrasive. The ends of the plates along the axis 2b.

Claims (5)

1. A method for the manufacture of axial assemblies of hyodynamic bearing equipment. This includes a cylindrical body with a bottom section. Which consists of the said axis, which has been It is inserted into such a housing and has an axial section and an axial plate that is firmly fixed on the track That axis The radial bearing section, which supports the said axial part in a condition that does not occur. Contact in the radial direction with fluid hydrodynamic action Causing Up in the radial bearing gap And the axial bearing section, which will support the axial plate Dang said in a condition that does not occur in axial direction contact with fluid hydrodynamic action, which takes place in the axial bearing gap, which consists of a process of Forming such axial components that have such axial segments and such axial plates. Grinding of surfaces along the outer circumference of the axial part; And the surface of the surface at the end of the sheet along the said axis While supporting the surface along the The polished outer circumference of the axial part is provided with a support assembly, which is The hardness of the surface is greater than the surface hardness of the surface along the outer circumference of the contour. The axis after polishing the outer circumference of the axial part. 2.Methods for the manufacture of axial assemblies of hydrodynamic bearing equipment. As discussed in claim 1, where the sliding motion is made by rotation. The axial portion between the surfaces along the outer circumference of the axial segment. And supporting assembly pieces 3.Methods for the manufacture of axial assemblies of hydrodynamic bearing equipment. As discussed in Clause 1 or 2, where the roughness of the surface of the surface along the circumference The outside of the axial segment in the axial direction is 0.04 μm or less, in the point of the arithmetic mean deviation Ra and the surface roughness of the distal surface. Of such axial plates in the circumferential direction is 0.04 μm or less in the point of deviation on the arithmetic mean Ra. 4. Hydrodynamic bearing devices which include; Cylinder-shaped body with a bottom section An axial assembly that has been inserted into the said housing and has an axial assembly. Which has been inserted into the aforementioned housing and has an axial portion And axial discs, which are tightly packed Located at the said axial section; The radial bearing, which will support the said axial part in The condition in which no radial contact occurs with fluid hydrodynamic action. Which causes a radial eye bearing gap; And the axial bearing section, which will support the plate along These axes are in a condition that does not occur in the axial direction by action. Fluid hydrodynamics Which makes it happen in the axial bearing gap facing The surface at the ends of the sheet along such axes; Where the surface along the outer circumference of the along Such axes will have an abrasive texture in the circumferential direction. And small overhangs that make up The roughness of such a surface will be smoothed. And the surface at the ends of the sheet along the axis There will be a cross-sectional intersection. 5. Hydrodynamic bearing devices described in Clause 5 where the roughness Of the surface of the surface along the outer circumference of the axial part in the direction along The axial orientation is 0.04 μm or less. On the issue of the arithmetic mean deviation Ra and the surface roughness of the surface at the ends of such axial plates in the direction along the The circumference is 0.04 micrometers or less. On the issue of the arithmetic mean deviation Ra