DE102009041531A1 - Spindle motor, particularly for hard disk drives, comprises base plate, and bearing bush, which is adhered with base plate, where adhesive gap is provided, which is formed between bearing bush and base plate for receiving adhesive - Google Patents

Abstract

The spindle motor (1) comprises a base plate (15), and a bearing bush (11), which is adhered with the base plate. An adhesive gap (17) is provided, which is formed between the bearing bush and the base plate for receiving an adhesive (18). The adhesive gap comprises an extending part (22) at one end, which is filled partially with the adhesive.

Description

The invention relates to a spindle motor, in particular for hard disk drives, with a base plate and with a bearing bush which is glued to the base plate, wherein an adhesive gap for receiving the adhesive is formed between the bearing bush and the base plate.

The side walls of the bearing bush and the base plate, which limit the adhesive gap, are formed substantially parallel. The adhesive gap formed therebetween has a uniform width which is in the range of about 10 μm. In the prior art, the adhesive gap is narrow as possible, so that a coaxial position of the bearing bush is achieved within the base plate without external adjustment. In order to accommodate a greater amount of adhesive in the nip, at least one sidewall has one or more adhesive pockets, which may be formed by, for example, one or more spaced-apart circumferential grooves. These glue bags are also just a few microns deep.

Spindle motors, especially in hard disk drives, have to withstand very high mechanical loads. The adhesive bond must accordingly have high holding forces. A measure of this, for example, the force that is required to press the bearing bush axially from the base plate, the so-called extrusion force. In order to test the adhesive strength, in particular the extrusion force, the spindle motors are subjected to a so-called shock test, in which the spindle motors are exposed to short bursts in the millisecond range with accelerations up to 1200 g on impact. The acceleration acts, for example, in the axial direction on the entire spindle motor. The bushing is thereby deflected relative to the fixed edge of the base plate. The adhesive bond is subjected to a shear load and at one end of the adhesive bond a nip load, caused by the deformation of the side surfaces of the adhesive bond in the base plate in axial shock. Due to the nip load, the adhesive layer is stretched radially in some places and compressed at other points. The radial change of the adhesive layer thickness is typically in the range of 2 μm to 4 μm or larger and exceeds the elongation at break of the adhesive.

Due to the limited elongation at break of the adhesive, that is, the maximum elongation before the adhesive breaks, of approximately 10% -20% of the adhesive layer thickness, the adhesive bond ruptures in places or at all with such large adhesive gap changes. The adhesive bond is weakened or completely released, which reduces the extrusion force. Repeated shock load is a gradual, increasing weakening of the adhesive bond until it breaks completely and the bearing bush released from the base plate and thus the spindle motor is destroyed.

By a general broadening of the adhesive layer thickness, the problem can not be solved, since the stability of the spindle motor is significantly weakened overall. An increase in the adhesive bags also does not lead to a significant improvement in the holding force.

The object of the invention is therefore to provide a spindle motor of the type mentioned above, which has a high extrusion force, which is not reduced by mechanical shock loads.

This object is achieved in that the adhesive gap has an extension at least at one end of the adhesive bond, which is at least partially filled with adhesive and thus the adhesive layer thickness, at locations of high strains in the adhesive and nip load is increased.

The invention is based on the finding that, in the case of an axial shock load, the greatest elongation of the adhesive occurs at only one end of the adhesive connection, depending on the fall direction during the shock test.

The extension is wider than the adhesive pockets, allowing the adhesive to provide greater maximum elongation. It is particularly expedient if the elongation at break of the adhesive within the extension is greater than the maximum elongation of the extension in the event of a shock load. Thus, the stress within the adhesive is less than the breaking tensile strength. A tear of the adhesive is thereby prevented.

The extension can occupy 10% to 90% of the total length of gluing gap and extension.

In the axial shock test of a spindle motor two different drop directions are possible in the test. Since, in the case of an axial shock load, the greatest stress in the adhesive occurs due to stretching on the outwardly pointing end of the adhesive gap, the extension is expediently arranged at this end of the adhesive gap.

So that the voltage curve within the adhesive is favorably influenced, it is advantageous if the extension has at least one oblique boundary wall. It is particularly advantageous if the boundary wall is formed obliquely on the bearing bush.

Depending on the elongation at break of the adhesive and the length of the extension in the axial direction, the oblique boundary wall must be provided with a corresponding opening angle, preferably between 5 ° and 60 °.

Preferably, the extension is completely bounded on at least one side by the oblique boundary wall. That is, the extension has no level or paragraph. This prevents local stress peaks, which lead to a breakage, to occur at a shoulder edge.

An alternative embodiment of the invention provides that the extension has two oblique boundary walls. Again, it is advantageous if the extension is completely bounded on both sides by the sloping walls, so that a V-shaped extension is created.

Thus, the elongation at break in the adhesive is not reached, it is useful if the adhesive in the extension about 5 times to 20 times wider than the bonding gap, starting from a bonding gap of 5 to 10 microns.

In a further preferred embodiment of the invention, the adhesive gap has an extension at both ends. The second extension achieves the same effect for the opposite axial shock direction.

In order to improve the strength of the adhesive bond, it is possible that in each case different adhesives are arranged in the adhesive gap and in the extension. Since in the outer area of the extension, the elongation at a shock load is particularly large, it is advantageous if the adhesive in the extension is tougher than the adhesive in the adhesive gap. The tough adhesive has a greater elongation at break and therefore tears only at higher strains in the adhesive layer, which occur only in shock tests outside the specification. The strength of the adhesive bond can be increased by a high strength adhesive with lower elongation at break in the bonding gap.

The invention is explained in more detail with reference to the accompanying drawings.

It shows:

1 a spindle motor according to the prior art,

2 an enlarged detail in the region of the adhesive gap of a spindle motor according to the invention with a V-shaped extension at the outer end of the adhesive gap,

3 a schematic drawing of a first embodiment of the invention with a V-shaped extension,

4 a schematic representation of another embodiment of the invention with two extensions, each with an oblique boundary wall and

5 a schematic representation of another embodiment of the invention with an extension with an oblique boundary wall and two adhesive bags.

The 1 shows you as a whole 1 referred to spindle motor according to the prior art as a rotary drive for a hard disk drive 2 ,

The spindle motor 1 has a rotor 3 with a hub 4 and a rotor magnet 5 and a stator 6 with a stator core 7 and stator windings 8th , which together make up the electric drive. Furthermore, the spindle motor 1 a hydrodynamic bearing system 9 with a wave 10 and a bearing bush 11 as is widely known in the art.

In the example are two radial bearings 12 between the wave 10 and the bearing bush 11 arranged and a thrust bearing 13 between the bearing bush 11 and the hub 4 , Camps 12 . 13 are each through storage structures 14 formed when turning the shaft 10 Build up a hydrodynamic pressure in the bearing fluid.

The design of the hydrodynamic bearing system 9 is not essential to the invention. The spindle motor 1 could also be equipped for example with plain bearings or bearings.

The spindle motor 1 still has a base plate 15 which forms part of the HDD enclosure. The bearing bush 11 of the hydrodynamic bearing system 9 is in a receiving opening 16 with clearance in the base plate 15 used. The thus between bearing bush 11 and base plate 15 formed adhesive gap 17 is complete with glue 18 filled to create a solid connection.

The glue gap 17 is in the example about 5 microns wide. In addition, the boundary walls have 19 . 20 the glue gap 17 at the bearing bush 11 and on the base plate 15 one or more peripheral adhesive bags 21 on.

According to specification, the hard disk drive must 1 withstand an acceleration up to 1200 g, which is axial to the bearing bush 11 acts. In such a shock load, the bearing bush 11 opposite the base plate 15 deflected, causing the adhesive gap 17 in places stretched or compressed. In the glue 18 this creates tensions. Are the tensions greater than the tensile strength of the adhesive 18 Occurs in places to break or tear the adhesive bond. This occurs especially in the places where the stretching of the adhesive gap 17 greater than the breaking elongation of the adhesive 18 , Repeated impact may cause the break in the adhesive 18 spread out and lead to total failure of the adhesive bond.

The adhesive 18 For example, has an elongation at break of about 10% of its width in the stretching direction, so that at a gap width of the adhesive gap 17 from 10 μm the maximum elongation, until breakage, is only 1 μm. In the case of shock loads within the specification, however, in places strains of the adhesive gap occur 17 in the range of 2 microns to 4 microns. Therefore, the adhesive bond breaks at these points and weakens the entire adhesive bond.

The 2 shows a spindle motor 1 According to the invention, in which, in contrast to the spindle motor according to 1 the glue gap 17 between bearing bush 11 and base plate 15 an extension 22 comprising, at least partially, with adhesive 18 is filled.

The extension 22 is at the end of the glue gap 18 arranged, the outside of the spindle motor 1 is facing, since the largest strain occurs here in a blow from above. The extension 22 is formed in the example V-shaped and is completely on both sides by oblique boundary walls 19 . 20 limited. This has the bearing bush 11 and the base plate 15 one chamfer on the edge to the glue gap 18 , The opening angle A of the extension 22 total is about 60 °, wherein the opening angle C of the boundary walls 19 . 20 are each substantially the same and amount to about 30 °. The opening angle C of the two boundary walls 19 . 20 However, they can also be different and are each preferably in the range between 5 ° and 60 °. Alternatively, only one boundary wall 19 , in particular at the bearing bush 11 be formed obliquely. The extension 22 and the glue gap 18 are in 3 illustrated schematically. The width Bs of the glue gap 17 is in the example about 10 microns. The width of the extension 22 is more than 200 μm at the open end. The extension 22 is about halfway with adhesive 18 filled and the width Bk of the adhesive 18 within the extension 22 is about 100 microns. The adhesive 18 in the extension 22 is about 10 times wider than the adhesive 18 in the glue gap 17 , Decisive for the invention is only the width Bk of the adhesive 18 , which is easily varied by the filling height of the extension.

At an elongation at break of 10%, the adhesive can 18 in the extension to a maximum of about 10 microns are stretched before it breaks or breaks. The strain due to the maximum shock load within the specification of the spindle motor 1 is, however, a maximum of 2 microns to 4 microns. The adhesive 18 in the extension therefore does not break in such a shock load. This maximum elongation only occurs at the end of the glue gap 18 in the field of enlargement 22 on, which is why the glue 18 in the glue gap 17 also does not break.

Overall, the entire adhesive bond remains intact with a maximum shock load and retains its full strength. Accordingly, the adhesive bond is not weakened by repeated shocks.

The 4 shows schematically a further embodiment of the invention. The glue gap 17 has in this embodiment at both ends an extension 22 on. The extension 22 at the outer end 23 the glue gap 18 has a sloping boundary wall 19 passing through a chamfer on the bearing bush 11 is formed and a straight boundary wall 20 at the base plate 15 , The extension 22 at the inner end 24 the glue gap 18 is structured the same way.

In the example, the extension has the inner end 24 a slightly larger opening angle B than the extension at the outer end 23 , However, the angles B can also be the same or have different proportions. The axial length of the extensions can be the same or different as in the example.

In this version is in the extensions 22 another glue 25 as in the glue gap 17 used. The adhesive 25 in the extensions, for example, may be tougher so that a greater elongation at break is achieved. This allows the extension to be slightly narrower, requiring less glue. The adhesive 18 in the glue gap 17 may be a high strength adhesive to achieve sufficient overall strength.

The extension at the inner end 24 the glue gap 18 stabilizes the adhesive bond in addition and increases the extrusion force, as the adhesive 18 in the extension 22 how an additional anchoring works. Also in this embodiment, the width Bs of the adhesive gap 17 about 10 μm. The adhesive layer thickness Bk is in both extensions 22 about 60 microns, and thus about six times the adhesive gap width Bs.

The 5 schematically shows a further variant of the invention. The extension 22 is formed here by a sloping boundary wall 19 ' and a straight boundary wall 20 ' , Adhesive pockets are on both boundary walls 21 ' formed in the form of punctures. The glue bags 21 ' are here with glue 25 filled and provide additional axial support as a kind of anchorage. It is also conceivable to fill the adhesive bags only partially with adhesive in order to achieve an additional widening of the adhesive gap or an increase in the adhesive layer thickness.

The adhesive gap width Bs, the width of the extensions Be and the adhesive layer thickness Bk can be adjusted depending on the desired extrusion force and impact resistance depending on the adhesive tensile strength and elongation at break. The stated values are intended as an example only and are in no way limiting. Rather, these variables are variable within wide ranges. For high impact loads, the dimensions can also be selected beyond the stated ranges.

LIST OF REFERENCE NUMBERS

1

spindle motor

2

Hard Drive

3

rotor

4

hub

5

rotor magnet

6

stator

7

stator core

8th

stator

9

hydrodynamic bearing system

10

wave

11

bearing bush

12

radial bearings

13

thrust

14

bearing structure

15

baseplate

16

receiving opening

17

bonding gap

18

adhesive

19, 19 '

Boundary wall bearing bush

20, 20 '

Boundary wall bearing bush

21, 21 '

adhesive pocket

22

extension

23

outer end of the extension

24

inner end of the extension

25

adhesive

A

Opening angle extension

C

Opening angle boundary wall

bs

Wide adhesive gap

Bk

Adhesive Thickness

Claims (13)

Spindle motor, in particular for hard disk drives, with a base plate ( 15 ) and with a bearing bush ( 11 ), which are connected to the base plate ( 15 ) is glued, wherein between bearing bush ( 11 ) and base plate ( 15 ) an adhesive gap ( 17 ) for receiving the adhesive ( 18 ), characterized in that the adhesive gap ( 17 ) at least at one end ( 23 . 24 ) an extension ( 22 ), which at least partially with adhesive ( 18 ) is filled. Spindle motor according to claim 1, characterized in that the extension ( 22 ) at the outward facing end ( 23 ) of the adhesive gap ( 17 ) is arranged. Spindle motor according to claim 1 or 2, characterized in that the breaking elongation of the adhesive ( 18 ) within the extension ( 22 ) is greater than the maximum elongation of the extension. Spindle motor according to one of claims 1 to 3, characterized in that the extension ( 22 ) at least one oblique boundary wall ( 19 . 20 ) having. Spindle motor according to claim 4, characterized in that the oblique boundary wall ( 19 . 20 ) has an opening angle (C) between 5 ° and 60 °. Spindle motor according to claim 4 or 5, characterized in that the extension ( 22 ) at least on one side completely by the oblique boundary wall ( 19 . 20 ) is limited. Spindle motor according to one of claims 4 to 6, characterized in that the extension ( 22 ) two sloping boundary walls ( 19 ) having. Spindle motor according to one of claims 1 to 7, characterized in that the adhesive ( 18 ) in the extension ( 22 ) is approximately between 5 times to 20 times wider than the adhesive gap ( 17 ). Spindle motor according to one of claims 1 to 8, characterized in that the adhesive layer thickness (Bk) in the extension ( 22 ) is at least 25 μm. Spindle motor according to one of claims 1 to 9, characterized in that the width (Bs) of the adhesive gap ( 17 ) is between 5 μm and 10 μm and the adhesive layer thickness (Bk) in the extension ( 22 ) is between 25 μm and 200 μm. Spindle motor according to one of claims 1 to 10, characterized in that in the adhesive gap ( 17 ) and in the extension ( 22 ) each different adhesives ( 18 . 25 ) are arranged. Spindle motor according to one of claims 1 to 11, characterized in that the adhesive ( 25 ) in the extension ( 22 ) has a higher elongation at break than the adhesive ( 18 ) in the adhesive gap ( 17 ). Spindle motor according to one of claims 1 to 12, characterized in that the adhesive gap ( 18 ) at both ends ( 23 . 24 ) one extension each ( 22 ) having.

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