Single piece hub with integral upper and lower female cones and method for making the same

Abstract

To simplify fabrication of an integral hub piece, the opening between the upper and lower female cones in this hub has sufficient width or radial dimension to allow access to both cones from one side of the hub with the cutting tool. A cutting tool is used which has a width smaller than the opening between the cones. Preferably, the tool has a width which is about equal to or smaller than an angular dimension through this opening which is defined by extending surfaces of the upper and lower female cones. If this limitation is satisfied, both cones can be created with a single machine set up operating from one side of the integrated hub.

Description

FIELD OF THE INVENTION

[0002] The present invention relates to the field of fluid dynamic bearings, and more specifically to a process for accurately cutting the conical surfaces into a hub to define the hub faces for a conical bearing, so that the motor hub is designed as a single component.

BACKGROUND OF THE INVENTION

[0003] Fluid dynamic bearings have come into increasingly wide-spread use, especially in fields where the stability of the shaft and bearing assembly is of critical importance, such as in the field of disk drives and the like. Ball bearing assemblies have many mechanical problems such as wear, run-out and manufacturing difficulties. Moreover, resistance to operating shock and vibration is poor because of flow damping. Thus, fluid dynamic bearings where in a lubricating fluid such as gas or liquid or air provides a bearing surface between a fixed member of the housing and a relatively rotating member have come into increasingly wide-spread use. Such fluid dynamic bearings spread the bearing surface over a large continuous area in comparison with the ball bearing assembly which comprises a series of point interfaces. This is desirable because the increased bearing surfaces reduce wobble or run-out between the rotating and fixed members. Further, improved shock resistance and readiness is achieved with a fluid dynamic bearing. Also, the use of fluid in the interface area imparts damping effects to the bearing.

[0004] An especially desirable design is a conical bearing, as a single bearing or a pair of facing bearings can impart substantial radial and axial stability to a system.

[0005] However, due to nominal gaps in a conical fluid bearing on the order of 1 to 3 microns, precise size and positional control must be maintained during component fabrication and assembly. If not done, the assembled components will not have the proper geometric relationships necessary to produce a functional air bearing when the parts rotate at the operating speed.

SUMMARY OF THE INVENTION

[0006] For purposes of this description, a dual conical fluid bearing spindle includes four basic components. These components are the upper male cone/shaft, the upper female cone, the lower male cone/shaft and the lower female cone. According to the present invention, the upper and lower female cones are integrated into a single part, more specifically the hub. This hub, in designs of a disk drive or the like where the shaft is fixed, may support an external flange for supporting one or more disks for rotation with the hub.

[0007] To simplify fabrication of this integral hub piece, the opening between the upper and lower female cones in this hub has sufficient width or radial dimension to allow access to both cones from one side of the hub with the cutting tool. A cutting tool is used which has a width smaller than the opening between the cones. Preferably, the tool has a width which is about equal to or smaller than an angular dimension through this opening which is defined by extending surfaces of the upper and lower female cones. If this limitation is satisfied, both cones can be created with a single machine set up operating from one side of the integrated hub.

[0008] Preferably the tool should only move orthogonal or parallel to the cutting tools rotational center axis.

[0009] This assembly design and fabrication technique eliminates the tolerance accumulation associated with the assembly of separate upper and lower female cones. Further, since the component manufacturing operation is done on the same machine set-up, there will be no error associated with rechucking the hub between two separate fabrication operations.

[0010] Other features and advantages of the present invention will become apparent to a person of skill in the art who studies the following invention disclosure given in association with the following set of drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

[0011] FIGS. 1A and 1B are exploded views of the basic components of a dual cone fluid dynamic bearing;

[0012] FIG. 2 is a modified version of FIG. 1 showing in this instance the integrated upper and lower female cones which are a subject of the present invention;

[0013] FIG. 3 is a vertical section of the integrated hub comprising the upper and lower female cones and with the essential dimensions of the present invention illustrated;

[0014] FIG. 4 is a vertical sectional view similar to the view of FIG. 3 illustrating the cutting tool, the width of the opening, and the width of the tool which is used to cut both the upper and lower cones according to the present invention;

[0015] FIG. 5 is a modified version of FIG. 4 showing cutting of the lower cone of the integrated cones; and

[0016] FIG. 6 shows the integrated hub comprising the upper and lower female cones, the upper male shaft/cone and the lower male shaft/cone all integrated into an exemplary motor in which the fluid dynamic bearing is useful.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

[0017] A typical conical fluid bearing spindle has the basic parts shown in FIG. 1A comprising an upper male cone/shaft element 10, an upper female cone 12, a lower male cone/shaft element 14 and a lower female cone 16. Typically, each of these pieces is separately fabricated. The pieces can then be assembled by joining the upper and lower female cones 12, 16. The shaft 22 of the upper male cone/shaft 10 is then inserted into the bore 24 of the lower male cone/shaft 14. Prior to doing this, of course, the upper female cone 12 and lower female cone 16 must be joined together, perfectly aligned. A further alternative appears in FIG. 1B where the male cones slide over or are otherwise fitted on a shaft which is inserted through the openings 65 in the cone sections 12, 16 which are joined as above. Due to the nominal gaps in a conical fluid bearing being on the order of 1 to 3 microns, precise size and positional control must be maintained during component fabrication and assembly. If not, the assembled components will not have the proper geometric relationships necessary to produce a bearing when the parts rotate at operating speed. Fabrication technology does exist to manufacture each of the individual components of FIGS. 1A and 1B to a high degree of precision. However, it is evident that to improve the positional control of the components in the assembly, that it would be highly desirable to produce an integrated hub 50 as shown in FIG. 2. This integrated hub would include both the upper and lower female cones 52, 54, respectively integrated into a single part.

[0018] The successful final machining process for this single piece hub 50 shown in its rough cast or machined form in FIG. 3 relies primarily on two dimensions marked as 60 and 62 in FIG. 3. Dimension 60 is the radial width of the opening 65 between the upper and lower female cones; dimension 62 is the angular width of the opening, which may be defined as the distance between two lines which extend from inner surfaces of the cone. The dimension 60 is set large enough to allow the shaft of the combination cones/shaft 10, FIG. 2 to pass through the opening 60. In the present example, the shaft 22 is shown attached to the cone 23; obviously, the shaft could equally well be attached to the lower cones/shaft 14 with the bore 24 appearing in the upper male cones/shaft 10. In a further alternative, the dimension 60 could be set large enough to allow for joinder of two mating surfaces of an upper and lower male cone 41, 43 as in FIGS. 1A and 1B. However, such an approach is more difficult to assemble accurately and stabilize as the two pieces must be joined inside the integral hub 50.

[0019] The critical dimension is the dimension 62 which is the dimension defined at the center line 65 of the opening between the upper 67 and lower 66 cone openings in the integral hub piece 50. The dimension 62 is defined and extends between a first line 70 drawn colinear with the conical surface of the upper cone and a second line 74 drawn parallel to line 70 and colinear with the conical surface of the lower hub female cone 76.

[0020] The significance of this dimension 62 becomes apparent from a comparison of FIGS. 4 and 5 which show the use of an exemplary tool for cutting on the surfaces 52, 54 of the upper and lower cones 67,66. This tool 90 mounted on a support shaft 92 is designed to have a width 94 which is less than (or about equal to) the dimension 62 (FIG. 3) defined by the opening between the two surfaces 72, 76 (FIG. 3). It is evident from a comparison of the figures that the dimension 94, which represents the width of the tool, must be less than or about equal to the dimension 62 which is the angular width of the opening defined by the lines 70,74 extending parallel to selected parallel surfaces of the upper and lower cones. In this way, the tool 90 may first cut the surface 52 of the upper cone, and then be pushed through the opening 65 to cut the surface 54 of the lower cone 66. By adopting this approach, access to both cones 66, 67 from one side of the hub is achieved. With a cutting tool 90 having a dimension 94 less than the critical angular opening dimension 62, both female cones 66,67 defined by their surfaces 52,54 can be created with a single machine set-up. This assembly design and fabrication technique eliminates the tolerance accumulation associated with the assembly of separate upper and lower female cones into a single hub with a single unitary hub being substituted. Furthermore, since the component manufacturing operation is done in a single machine set-up, there is no error associated with rechucking the hub between two separate fabrication operations. Therefore, the highly precise dimensions of the cones can be achieved. Finally, either the part being cut, or the cutting tool can move in forming the female conical surfaces.

[0021] This approach using a single unitary hub can be used to establish either a rotating hub, rotating about a fixed shaft, or a fixed hub with a rotating shaft. For example, referring back to FIG. 2, it can be seen that hub 50 of FIG. 2 includes a disk support ledge 100, so that the hub as it rotates about the integrated shaft 10, 14 can support one or more disks for rotation. In contrast, in FIG. 6 a complete motor is shown incorporating the unitary hub 50 of the present invention with a extended portion 110 of the hub supporting a magnet 112 which cooperates with a stator 114 to drive a motor. The same external portion 110 of the hub 50 rotates within a recess in base 120 which may be incorporated into a disc drive or the like. A disc support surface can be provided on the hub.

[0022] Other features and advantages of the present invention may become apparent to a person of skill in the art who studies this disclosure. Therefore, the scope of the invention is to be limited only by the following claims.

Claims

1. A dual conical fluid dynamic bearing comprising an integral male cone/shaft element, an integral male cone/bore element, an integral single piece hub having first and second female cones defined therein and joined by a central opening, said male cone/shaft element and said male cone/bore element being joined through said central opening and supported by a fluid for relative rotation.

2. A fluid dynamic bearing as in claim 1 wherein said male cone/shaft element comprises a conical element and a shaft extending axially away from a narrow end of said cone.

3. A fluid dynamic bearing as in claim 2 wherein said male cone/bore element comprises a cone with a shaft extending axially away from a wide end of said cone and further having a bore extending through said cone and said shaft, said shaft of said integral cone/shaft element fitted into said bore of said cone/bore element to accurately position said cone of said cone/shaft element relative to said cone of said cone/bore element.

4. A method of forming an integral, one piece hub for a dual conical fluid dynamic bearing comprising: defining a center hole having an opening dimensioned to accommodate a narrow end of each cone of a dual conical bearing, as well as passage of a tool for cutting surfaces of each of a pair of female cones in said hub defining each of a pair of female cones in said integral hub utilizing the tool which has a width dimension less than or equal to the angled dimension through the central opening so that each of said pair of female cones may be cut from one side of said hub.

5. A method as claimed in claim 4 in which the hole is dimensioned to accommodate the tool passing from one of the cones to the other of the cones without substantially changing the angle of the tool relative to a central axis of the integral hub.

6. A method as claimed in claim 5 wherein a maximum dimension for the tool is defined by drawing a line over a projected finished surface for each of said cones through the hole through which the tool passes, the distance between the lines establishing a maximum width of the tool.

7. A method as claimed in claim 6 wherein the distance between the lines is established at the center hole of the integrated hub.

8. A dual conical fluid dynamic bearing comprising a hub having first and second female cones defined therein and joined by a central opening, the central opening being a sufficient width to accommodate means for serially cutting the first and second cones without modification of setup of said hub relative to said cutting means.

9. A fluid dynamic bearing as in claim 8 wherein said means for cutting cuts said conical surfaces serially.