DE102012013186A1 - Spindle motor for driving disk of storage disk drive assembly of electronic device e.g. laptop computer, has base plate and cover formed as portion of housing of electronic device - Google Patents

Abstract

The spindle motor comprises a base plate (12), and motor component attached to the base plate. A fluid dynamic bearing system is provided for pivot bearing of the movable component relative to the stationary motor component about a rotation axis. An electromagnetic driving system is provided for the rotational drive motor of the movable component. The base plate or the cover arranged on the base plate, are formed as portion of the housing (14) of the electronic device. Independent claims are included for the following: (1) a storage disk drive assembly; and (2) an electronic device.

Description

Field of the invention

The invention relates to a spindle motor for driving at least one storage disk of a disk drive, in particular a magnetic or optical disk drive.

State of the art

Spindle motors for driving disk drives are well known in the art. In particular, spindle motors are used which are mounted by means of a fluid dynamic bearing system. A typical spindle motor of the type described with fluid dynamic bearing system is in the DE 10 2009 031 219 A1 disclosed. It is a spindle motor for driving 2.5 "disk drives, which drives 2.5" disks.

Such disk drives are incorporated into electronic devices such as laptops, netbooks, video players or similar devices as inexpensive mass storage.

In recent times, so-called tablet PCs are becoming increasingly popular, which are portable and in particular very flat. Due to the flat design with a case height of, for example, less than 10 mm, conventional disk drives can not be installed as mass storage devices in these devices because these hard disk drives themselves have a height of 9.5 mm or more by default. Previously known hard disk drives usually consist of a base plate, which serves as a mounting platform for the engine components z. As the stator, the actuator for the read / write unit, the PCB and other mechanical and electronic components and with a screwed metal cover (top cover) z. B. is closed as a seal against environmental particles.

Therefore, instead of hard disk storage drives, semiconductor memories, for example so-called flash memories, have hitherto been used in these devices. However, compared to hard disk memories, these semiconductor memories are relatively expensive, so that the aim is to also use inexpensive mass memories in the form of disk drives in the tablet PCs. However, this can not be realized with conventional disk drives, so there is a need for very low profile hard disk drives.

The company Seagate Technology, USA, has launched flat hard disk storage with a height of 7 mm under the name Momentus ^® Thin. These hard disk drives are conventionally built into a dedicated closed case, and this case is then rebuilt into a larger case of the electronic device. A reduction of the overall height can be achieved, for example, by drastically reducing the bearing distance of the two radial bearings of the fluid-dynamic bearing system, or merely providing a single radial bearing instead of two radial bearings subject to one another. However, this can lead to a reduction in the bearing stiffness and running accuracy of the leaching plant, so that measures must be taken to ensure the required bearing stiffness. For storage drives with high storage density, the running accuracy of the bearings is crucial so that the writing and reading of the data on the disk is reproducible at all with the required accuracy.

Disclosure of the invention

It is therefore the object of the invention to provide a spindle motor for driving a disk drive, which allows to realize disk drives with a height of less than 6 mm.

This object is achieved by a spindle motor with the features of claim 1.

Preferred embodiments of the invention and further advantageous features are specified in the subclaims.

The spindle motor for driving a storage disk of a disk drive is suitable for installation in a housing of an electronic device and comprises a base plate, at least one fixed engine component mounted to the base plate, at least one movable engine component, a fluid dynamic bearing system for pivotally mounting the movable engine component relative to the stationary engine component about an axis of rotation, and an electromagnetic drive system for rotationally driving the movable engine component.

The invention is characterized in that either the base plate or the cover, or the base plate and the cover are formed as part of the housing of the electronic device.

In a preferred embodiment of the invention, only the base plate in one piece, d. H. So be formed as an integral part of the housing of the electronic device.

In another embodiment of the invention, only the cover is formed as an integral component of the housing of the electronic device.

In a particularly preferred embodiment of the invention, however, both the base plate and the cover are in one piece, that is formed as an integral component of the housing of the electronic device.

By the invention, a drastic reduction in the height of the spindle motor is possible because the housing of the electronic device is now formed as part of the spindle motor, so that a separate housing for the spindle motor or the finished memory disk drive deleted. There are no separately formed base plate and / or cover more necessary, but the housing of the electronic device is used instead of these components. This makes it possible to build a spindle motor or a hard disk drive with a height of less than 6 mm. Such a very flat spindle motor or hard drive can then be installed in appropriate tablet PCs, tablet readers, or other mobile devices and offers compared to semiconductor memory low-cost storage space of high capacity. A significant advantage of the invention is that the components of the spindle motor or the disk drive are installed directly in the housing of the electronic device, so that a separate housing enclosing the spindle motor or the disk drive is dispensed with. In the housing of the electronic device, in addition to the components of the spindle motor and disk drive above all a variety of other components and components are arranged, which are not part of the spindle motor or disk drive. The spindle motor or the disk drive represents only a small part of the built-in electronic device components. Additional components may be about a screen and an input device, such as a keyboard, the keyboard integrated as a touch screen in the screen can be. Other components of the electronic device are about a microprocessor and a semiconductor memory as a supplement to the disk drive, also collectively referred to as hybrid memory.

The storage disk of the disk drive is attached to the movable motor component, and read / write devices for writing and reading data to and from the storage disk are arranged on the base plate.

The disk drive is particularly designed as a magnetic disk drive in the form of a hard disk drive.

This hard disk drive is now separate from the other components and dust-tight encapsulated in the housing of the electronic device.

For example, the spindle motor with hard disk drive is first mounted and encapsulated first in the housing of the electronic device in a suitable clean room. Thereafter, the remaining components of the electronic device can be mounted outside of the clean room or in a less classified clean room. The encapsulation of the disk drive does not allow any contaminants to enter the disk drive.

In an alternative embodiment of the invention, the hard disk drive can also be arranged as a detachable unit in a recess of the housing of the electronic device. In this case, the hard disk drive forms a removable part of the housing of the electronic device, which is integrated in shape and design in or on the electronic device, but is designed as a removable storage.

By integrating the disk drive in the respective electronic device, eg. As a tablet PC, which is usually equipped with an outer housing, and its preferably combined use as a cover for the disk drive can be dispensed with an additional separate housing cover. The saved height is thus available for functionally relevant components of the storage system, without an essential function of the disk drive is impaired. The replacement of the cover by the housing of the electronic device requires a coordinated geometries, sealing elements (on the device housing or on the base plate of the drive), optionally a fastening element for the shaft of the spindle motor (eg screw) and optionally further fasteners for the baseplate.

To protect the storage disk drive from environmental particles, a thin metal or plastic film or plate instead of the cover (top cover) can be attached in addition z. B. glued or shrunk, which closes the disk drive dust-tight and thus allows its mounting in the housing of the electronic device outside of a clean room. However, since pressure equalization is required, filters are used in a rigid cover or the cover is flexible. Alternatively, a pressure-compensating, flexible element is provided, which is arranged between the interior of the hard disk drive and the interior of the electronic device.

As a further embodiment can also be dispensed sidewalls and floor to the base plate when the functionally relevant components of the disk drive are mounted directly or on a minimized carrier body in the housing of the electronic device. The area of the disk drive can be partially isolated with a seal cover or a film against particles protected.

Furthermore, a base plate can be designed so that it is designed directly as a housing of the electronic device or as a mounting platform or frame for other mechanical and electronic components, such as circuit boards, screen. Thus, the disk drive assumes all or part of the housing function of the electronic device.

Likewise, a disk drive in the outer housing can be tuned to the electronic device that z. B. is docked to this and the housing function partially takes over.

Due to the low overall height of the spindle motor, the conventional methods for generating an axial preload for the fluid dynamic thrust bearing can not be used or only to a limited extent. It is therefore proposed to use for generating a magnetic biasing force at least one separate permanent magnet, which is arranged for example on the fixed motor component, preferably on the fixed bearing component, in the vicinity of a first sealing gap and is separated from the rotor component only by a narrow axial gap. The rotor component is made of ferromagnetic material, such as steel, and is magnetically attracted by the permanent magnet. This magnetic force acts axially counter to the force of the fluid-dynamic thrust bearing.

Brief description of the drawings

1 shows a section through a first embodiment of a hard disk drive according to the invention, which is integrated in a housing of an electronic device.

1A shows an enlarged section of the hard disk drive of 1 ,

2 shows a section through a second embodiment of a hard disk drive according to the invention, which is integrated in a housing of an electronic device.

2A shows an enlarged section of the hard disk drive of 2 ,

3 shows a section through a third embodiment of a hard disk drive according to the invention, which is integrated in a housing of an electronic device.

3A shows an enlarged section of the hard disk drive of 3 ,

4 shows a view of a fourth embodiment of a hard disk drive according to the invention as part of a housing of an electronic device.

5 shows an enlarged section of a hard disk drive in a opposite 2A modified embodiment.

6 shows a section through a hard disk drive according to the 5 ,

Description of preferred embodiments of the invention

The 1 and 1A show a first embodiment of a hard disk drive according to the invention 10 that in a housing 14 an electronic device is integrated. The hard disk drive 10 includes a base plate 12 , which serves as a mounting platform for the engine components and other mechanical and electronic components. The housing 14 of the electronic device into which the hard disk drive 10 is installed, serves as a cover for the hard disk drive 10 , This includes the base plate 12 a revolving raised edge, by sealant 20 is sealed and on the case 14 of the electronic device rests. The housing 14 of the electronic device is covered by a housing cover 16 locked. This can for example have a screen.

The hard disk drive 10 consists of the base plate 12 , with an opening into which a bearing bush 22 is included. The bearing bush 22 includes a bearing bore in which a shaft 24 by means of a fluid dynamic bearing about an axis of rotation 42 is rotatably mounted. The fluid dynamic bearing system comprises two radial bearings 44 . 46 placed between the adjoining surfaces of the bearing bush 22 and the wave 24 are arranged, and at least one fluid dynamic thrust bearing 48 , which between one end face of the bearing bush 22 and an opposite side of a rotor component 26 is arranged. The rotor component 26 is with the wave 24 firmly connected and is driven by an electromagnetic drive system. The electromagnetic drive system includes a stator assembly 30 , which is fixed to the base plate and consists of a number of stacked stator laminations, which are wound with stator windings. Further, a rotor magnet 32 provided, which of the stator assembly 30 opposite to the rotor component 26 is attached. On the rotor component 26 is at least one storage disk 34 arranged, which is used for recording and playback of electronic data. Side of the spindle motor and the storage disk 34 forms the base plate 12 a space 36 , which serves to arrange the mechanical and electronic components of the write-read device (not shown), by means of which data on the disk 34 written and can be read by this.

By using the case 14 of the electronic device as a cover for the hard disk drive 10 The overall height of the hard disk drive can be reduced. In a remaining space 38 of the housing 14 Furthermore, further components of the electronic device, such as electronic components, batteries, display devices and other can be installed.

The 2 and 2A show a second embodiment of the invention. In this embodiment, in particular parts of the housing 114 of the electronic device as a base plate for the hard disk drive 110 educated. This is the case 114 the electronic device corresponding to the engine components and other mechanical and electronic components of the hard disk drive 110 to be able to record.

How to particular in 2A detects, includes the housing 114 an opening in which a fixed bearing component 128 is attached. The fixed bearing component 128 takes a fixed shaft 124 on, whose free end with a cover 118 connected to the hard disk drive 110 particle-free closes, with the cover 118 on a circumferential edge of the housing 114 rests and by sealants 120 is sealed.

A rotor component 126 , which is a one-piece molded bearing bush 122 is on the fixed shaft 124 rotatably supported by a fluid dynamic bearing system. The rotor component 126 is driven by an electromagnetic drive unit, which is formed by a stator assembly 130 on the case 114 is attached, as well as a rotor magnet 132 attached to a circumferential edge of the rotor component 126 is attached.

The rotor component 126 for example, carries two disks 134 to which data can be applied and read by means of a read-write device (not shown). The read-write device is in a corresponding space 136 arranged laterally from the engine components and storage disks.

The housing 114 is by means of a housing cover 116 covered. In the remaining space 138 of the housing 114 Now, other components of the electronic device, such as electronic components, batteries, display devices, and other can be installed.

The 3 and 3A now show a third embodiment of the invention, in which the hard disk drive 210 turn in the case 214 of the electronic device is integrated. The housing 214 forms the base plate of the hard disk drive 210 for arranging the engine components and necessary mechanical and electronic components. At the outer edges of the hard disk drive 110 are sealants 220 arranged along with the assembled housing cover 216 the hard drive 210 Seal dust-tight.

As in 3A can be seen, includes the hard disk drive 210 a fixed bearing bush 222 placed in an opening of the housing 214 is arranged. In a bearing bore of the bearing bush 222 is a wave 224 arranged, which is rotatably mounted in the bearing bush by means of a fluid dynamic bearing system. A free end of the wave 224 carries a rotor component 226 which the storage disks 234 of the hard disk drive 210 wearing. The rotor component 226 is driven by an electromagnetic drive unit, which consists of a stator 230 exists on the housing 114 is arranged, and a rotor magnet 232 , which on the inner circumference of the rotor component 226 is arranged. In this embodiment, the hard disk drive 210 be particularly flat, because both the base plate and the cover of the hard disk drive are through the housing 214 or the housing cover 216 formed of the electronic device. The housing 214 is by means of a housing cover 216 covered. In the remaining space 238 of the housing 214 Now, other components of the electronic device, such as electronic components, batteries, display devices, and other can be installed.

4 shows an embodiment of the invention, in which the housing 314 the electronic device is a separate, preferably from the housing 314 removable housing part 315 having. In this housing part 315 is the hard disk drive according to the invention 310 integrated, which for example a base plate 312 as a mounting platform for the engine components and for other mechanical and electronic components, wherein the housing part 315 as a cover of the hard disk drive 310 serves. In a similar way as in 3 is shown, the housing part 315 but also both as a base plate and cover of the hard disk drive 310 be educated. The housing part 315 is to the rest of the housing 314 the electronic device docked and takes over part of its housing function. The advantage is that the hard drive 310 together with the housing part 315 can be replaced in the event of a defect or for the purpose of upgrading the storage capacity. Furthermore, the housing part additional batteries 340 exhibit.

5 shows a section of a hard disk drive 410 in one opposite 2A modified embodiment and is drawn to scale with specified scale. The in 2A shown spindle motor can directly against the in 5 be exchanged described spindle motor.

The spindle motor comprises a base plate 412 according to the invention as part of the housing 114 an electronic device (see 2 ) is trained. The base plate 412 has a substantially cylindrical opening in which a fixed bearing component 428 is included. The fixed bearing component 428 is substantially cylindrical and has at one end a radially inwardly directed edge 428a that defines an opening. It is also a wave 424 provided, which is approximately T-shaped in cross-section consists of three sections, a lower one 424a , a middle one 424b and an upper section 424c , The lower section of the shaft 424 consists of a flange 424a that has a larger diameter than the middle section 424b having the shaft. Thus, no additional link length and thus height for the connection between shaft 424 and bearing component 428 needed and the on the outer circumference of the shaft 424 and on the upper face of the flange 424a located surfaces can be machined relatively easily. The flange 424a the wave 424 is in by the edge 428a of the component 428 formed opening formed. Preferably, the border 428a and the flange 424a connected cohesively to one another at their contact surfaces, for example by means of a welded connection and / or adhesive connection.

The middle section 424b and the top section 424c the wave 424 are perpendicular to the base plate 412 and the fixed bearing component 428 and protrude axially beyond these components. At the top section 424c the wave 424 is an annular stopper component 425 arranged, preferably non-positively or cohesively on the shaft 424 is attached. The stopper component 425 has a much larger outer diameter than the shaft 424 in the middle section 424b having. The wave 424 points in the upper section 424c acting as a connection area with the stopper component 425 serves one opposite the middle section 424b reduced outside diameter. In the middle section 424b the wave 424 is the radial storage area. The base plate 412 , the wave 424 , the bearing component 428 and the stopper member 425 form the stationary motor component of the spindle motor.

The spindle motor comprises a rotor component 426 on which a cylindrical bearing bush 422 is integrally formed. The bearing bush 422 of the rotor component 426 has a cylindrical bearing bore through which the shaft 424 is inserted through and in which radial bearings are formed. The bearing bush is in one by the shaft 424 and the two components 425 and 428 formed gap relative to these components about an axis of rotation 442 rotatably arranged. The stopper component 425 is at least partially in an annular recess of the rotor component 426 arranged. The diameter of the recess is larger than the diameter of the bearing bore.

A bearing gap filled with a bearing fluid, for example a bearing oil 423 separates adjacent surfaces of the shaft 424 , of the flange 424a , the bearing bush 422 and the two components 425 . 428 from each other.

On the inner circumferential surface of the bearing bore of the bearing bush 422 two cylindrical radial bearing surfaces are formed. The radial bearing surfaces of the bearing bush 422 enclose the middle section 424b the fixed shaft 424 at a distance of a few microns to form an axially extending portion of the bearing gap 423 and form with each opposite radial bearing surfaces of the shaft 424 two fluid dynamic radial bearings 444 . 446 , The two radial bearings 444 . 446 are separated by a short separator section. Along the Separatorabschnitts has the bearing gap 420 a significantly greater radial gap distance compared to the radial bearing gaps.

The radial bearing surfaces of the two radial bearings 444 . 446 are for example provided with sinusoidal or parabolic radial bearing grooves. The radial bearing grooves 444a of the upper radial bearing 444 are preferably formed substantially symmetrical, which means that the part of the radial bearing grooves, which is arranged above the apex, is formed about the same length as the lower part of the radial bearing grooves. The pumping action of both parts of the radial bearing grooves 444a of the upper radial bearing 444 points towards the apex, ie to the center of the bearing, so that the radial bearing 444 becomes sustainable. There are due to the symmetrical design of the radial bearing grooves of the upper radial bearing 444 however, no net generated pumping direction that acts on the bearing fluid.

In contrast, the radial bearing grooves 446a of the lower radial bearing 446 preferably asymmetrically formed insofar as that the part of the radial bearing grooves, which is arranged below the apex, formed longer than the upper part of the radial bearing grooves. This creates on the one hand an increase in pressure within the bearing fluid in the direction of the apex of the radial bearing 446 , causing the radial bearing 446 becomes sustainable. On the other hand, a net pumping action is exerted on the bearing fluid which forces the bearing fluid axially upward toward the upper radial bearing 444 promoted.

Below the lower radial bearing 446 goes the axially extending portion of the bearing gap 423 in a radially extending portion, along which a fluid dynamic thrust bearing 448 is arranged. The thrust bearing 448 is by radially extending thrust bearing surfaces of the bearing bush 422 and corresponding opposite thrust bearing surfaces of the flange 424a the wave 424 educated. The thrust bearing ends radially outward on the outer circumference of the flange 424a and radially inward at the axially extending central portion 424b the wave 424 , The thrust bearing surfaces of the thrust bearing 448 are as to the axis of rotation 442 vertical circular rings formed. The fluid dynamic thrust bearing 448 is in a known manner by, for example, spiral thrust grooves 448a marked on either the lower end of the bearing bush 422 , the flange 424a the wave 424 or both parts are attached. On the surface of the edge 428a of the fixed bearing component 428 or the directly opposite surfaces of the bearing bush 422 No thrust bearing grooves are arranged. The between the flange 424a the wave 424 and the bearing bush 422 arranged radially extending thrust bearing gap is smaller than the axial gap between the bearing bush 422 and the edge 428a of the fixed bearing component 428 ,

In the bearing bush 422 is a recirculation channel 450 arranged, starting from a radially extending gap between the upper end face of the bearing bush 422 and an opposite end surface of the stopper member 425 obliquely down through the bushing 422 runs and radially outside of the thrust bearing 448 in a radially extending portion of a first capillary sealing gap 452 empties.

The sealing gap 452 joins the radial section of the bearing gap 423 in the radial outside of the thrust bearing 448 and is proportionally filled with bearing fluid. The sealing gap 452 is through surfaces of the bearing bush 422 and the bearing component 428 is limited and seals the end of the storage gap 423 from. The sealing gap 452 includes a short radially extending portion and a longer conically widening and nearly axially extending portion extending from an outer peripheral surface of the bearing bush 422 and an inner peripheral surface of the bearing member 428 is limited. In addition to the function as a capillary seal, the sealing gap is used 452 as a fluid reservoir and provides the required for the life of the storage system amount of bearing fluid. Furthermore, this allows filling tolerances and a possible thermal expansion of the bearing fluid can be compensated.

On the other side of the storage system is the bearing bush 422 the rotor member 426 following the upper radial bearing 444 designed so that it forms a radially extending surface, which with a corresponding opposite surface of the stopper member 425 forms a radial gap. Within this radial gap optional, but not necessarily spiral groove pump or thrust bearing grooves are provided. At the radial gap, an axially extending second sealing gap closes 454 which is proportionally filled with bearing fluid and the bearing gap 423 seals at this end. The second sealing gap 454 is made by opposing surfaces of the bearing bush 422 and the stopper member 425 limited and widens at the outer end with preferably conical cross section. In this case, the outer peripheral surface of the stopper member 425 in the course to the bearing exterior slightly inwards towards the axis of rotation 442 be inclined. The opposite inner peripheral surface of the bearing bush 422 runs either parallel to the axis of rotation 442 or is also slightly inclined inwardly, but the inclination angle is smaller than the inclination angle of the outer peripheral surface of the stopper member 425 , so that results in a conical capillary seal. The resulting angle between the inner peripheral surface of the bearing bush 422 and the outer peripheral surface of the stopper member 425 is significantly larger, preferably at least four times as large as the angle of the first sealing gap 452 formed between the inner peripheral surface of the bearing member 428 and the outer peripheral surface of the bearing bush 422 ,

The second sealing gap 454 preferably by a pumping seal 456 be complementary. The pump seal 456 includes pump groove structures 456a placed on the surface of the stopper component 425 or the bearing bush 246a are arranged. As the bearing rotates, the pump groove structures create 456a a pumping action on the second sealing gap 454 located bearing fluid. This pumping action is in the direction of the bearing gap 423 So in the direction of the radial bearings 444 and 446 directed.

The second sealing gap 454 is of a ring-shaped profiled cover 458 covered. The cover 458 is on an edge of the rotor component 426 attached and stuck there, for example, with the cover 426 on a radially extending, frontal surface of the rotor component 426 rests. An inner edge of the cover 458 forms together with a peripheral surface of the stopper member 425 an air gap as a gap seal. This increases the safety against leakage of bearing fluid from the seal gap 454 or reduces evaporation of the bearing fluid and thus increases the life of the fluid bearing.

At its axially outer end, the sealing gap widens 454 in a free space, which is preferably so large that it can accommodate the entire volume of bearing fluid in the warehouse. This clearance is used in particular for filling the bearing with bearing fluid. In this case, the bearing gap and the sealing gaps are preferably evacuated and the total volume of bearing fluid filled in the free space. Thereafter, the bearing gap is re-aerated, whereby the volume of bearing fluid from the space in the bearing gap and the sealing gaps is pressed.

The spindle motor has an electromagnetic drive system which is formed in a known manner by a on the base plate 412 arranged stator arrangement 430 of stacked stator laminations, and an annular rotor magnet concentrically surrounding the stator assembly at a distance 432 at an inner circumferential surface of the rotor component 426 is arranged. Shown is an external rotor motor, but without limitation, an internal rotor motor can be used, in which the stator assembly is arranged radially outside of the rotor magnet.

Since the spindle motor preferably only a single fluid dynamic thrust bearing 448 that points to the rotor component 426 a force in the direction of the stopper component 425 generated, a corresponding axial counterforce or biasing force is necessary, which is the rotor component 426 holds axially in the balance of forces. There are several possibilities for this.

The stator arrangement 430 and the rotor magnet 432 For example, they may be arranged axially offset from each other (magnetic offset), in such a way that the magnetic center of the rotor magnet 432 axially further away from the base plate 412 is arranged as the center of the stator assembly 430 , As a result, the magnet system of the motor, an axial force on the rotor component 426 exerted, opposite to the bearing force of the thrust bearing 448 acts.

Another known possibility is the use of a ferromagnetic pull ring 460 that is axially below the rotor magnet 432 is arranged and magnetically attracted by this. This magnetic force acts on the force of the fluid-dynamic thrust bearing 448 opposite. For very flat spindle motors with a height of 6 mm or less, this method is no longer meaningful applicable due to lack of space.

The preferred variant in the illustrated spindle motor is for the magnetic bias of the axial bearing at least one separate permanent magnet 462 to use, for example, on the fixed engine component, preferably on the fixed bearing component 428 near the top of the first sealing gap 452 is arranged. The permanent magnet 462 is at an axial in the direction of the rotor component 426 directed edge of the fixed bearing component 428 arranged, being between the permanent magnet 462 and the rotor component 426 an air gap remains adjacent to the opening of the sealing gap 452 is arranged.

The perment magnet 462 may be annular or consist of a plurality of individual magnets, which extend beyond the circumference of the fixed bearing component 428 are arranged distributed. The rotor component 426 is made of ferromagnetic material, such as steel, and is made by the permanent magnet 462 magnetically attracted. This magnetic force acts on the force of the fluid-dynamic thrust bearing 448 opposite.

It can be provided in the reverse manner, that of the permanent magnet 462 at the bottom of the rotor component 426 the edge of the fixed bearing component 428 is arranged opposite. In this case, there is the fixed bearing component 428 made of a ferromagnetic material and is made by the permanent magnet 462 magnetically attracted.

The three described methods of magnetic bias can either be applied individually or combined with each other.

This variant has several advantages. There is no magnetic offset and no pull ring necessary, which in particular deteriorate the acoustic properties of the spindle motor, since they produce rapidly changing magnetic forces when rotating the motor, which cause noise especially in the acoustic range. Furthermore, eliminates the braking effect, which occurs due to the formation of eddy currents when using a Zugsringes due to the changing magnetization de rotor magnet and previously had an increased power consumption of the engine result.

The permanent magnet 462 acts consistently on the rotor component 426 so that no rapidly changing magnetic forces occur that cause noise or eddy currents.

Another inventive effect of the magnetic bias with a separate permanent magnet 462 is a reduction in the escape of evaporated bearing fluid from the first seal gap 452 of the camp.

The permanent magnet 462 sits on the edge of the fixed bearing component 428 immediately opposite the rotor component 426 , Between the permanent magnet 462 and the rotor component 426 becomes a narrow air gap 464 formed in the form of a labyrinth seal. From the adjacent first sealing gap 452 vaporizing bearing fluid can only through this narrow air gap 464 exit from the warehouse. Due to diamagnetic properties of the fluid vapor is additionally characterized by in the air gap 464 acting magnetic field of the permanent magnet 462 in the sealing gap 452 retained. An escape of fluid vapor from the sealing gap 452 is significantly reduced.

Between the permanent magnet 462 and the stator assembly 430 is a cylindrical section of the base plate 412 arranged. If the base plate is made of ferromagnetic material, such as ferromagnetic steel, this cylindrical portion acts as a magnetic shield and reduces disturbing influences of the permanent magnet 462 on the magnetic properties of the stator assembly 430 ,

The invention finds particular application in spindle motors for a hard disk drive with magnetic disks having a diameter of 2.5 inches. Preferably, in the 1 to 6 The spindle motors shown have the following data and dimensions: Stator: Number A of stator plates: 3 to 8, preferably 4 to 6 (inclusive) Axial height B of the laminated stator core: 0.8 to 1.8 mm, preferably 1 to 1.4 mm Thickness C of the individual stator laminations: 0.15 to 0.35 mm, preferably 0.2 mm Tooth width D in the circumferential direction: 1 to 2 mm, preferably 1.2 to 1.6 mm Statornut-opening E in the circumferential direction: 0.8 to 1.8 mm, preferably 1 to 1.4 mm Stator outer diameter F for a storage disk: 14 to 18 mm, preferably 15 to 17 mm Stator outer diameter F for several disks: 18 to 22 mm, preferably 19 to 21 mm Rotor magnet: axial height G of the rotor magnet: 1.5 to 3.0 mm, preferably 2 to 2.5 mm Magnetic inner diameter H: 14.5 to 19 mm, preferably 16 to 18 mm Magnetic outside diameter I: 18.5 to 23 mm, preferably 20 to 22 mm Magnetic thickness J, radial: about 1 mm, preferably 0.8 mm to 1.4 mm radial contact length K from the axial top of the Rotor magnets at the bottom of the hub: 10% to 80%, preferably 30% to 60% Quotient of stator height / height of magnet: 40% to 80%

winding:

Preferably, enameled wire is used as the stator winding. Winding wire diameter: 0.1 to 0.2 mm, preferably 0.12 to 0.14 mm (measured without paint insulation) Number of turns per stator pole: 30 to 80, preferably 50 to 70

A magnetic offset (= distance between the magnetic centers of the stator and the rotor magnet), which is not equal to zero, is provided between the stator and the rotor magnet in order to generate an axial magnetic counterforce to the fluid bearings. Alternatively or additionally, a pull ring (attractive plate) is used to generate a magnetic bias. Alternatively or additionally, a separate permanent magnet for magnetic bias can be used. Magnetic offset L: 0.1 to 0.5 mm, preferably 0.3 to 0.4 mm

LIST OF REFERENCE NUMBERS

10, 110, 210, 310, 410

Hard Drive

12, 312, 412

baseplate

14, 114, 214, 314

casing

315

Housing part (removable)

16, 116, 216

housing cover

118

cover

20, 120, 220

poetry

22, 122, 222, 422

bearing bush

423

bearing gap

24, 124, 224, 424

wave

424a, 424b, 424c

Sections of the shaft 424

425

stop member

26, 126, 226, 426

rotor component

128, 428, 428a

bearing component

30, 130, 230, 430

stator

32, 132, 232, 432

rotor magnet

34, 134, 234

disk

36, 136, 236

Installation space (for read-write device)

38, 138, 238, 338

space

340

battery

42, 442

axis of rotation

44, 444, 444a

radial bearings

46, 446, 446a

radial bearings

48, 448, 448a

thrust

450

recirculation

452

Sealing gap, first

454

Sealing gap, second

456, 456a

pump seal

458

cover

460

pull ring

462

permanent magnet

464

air gap

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102009031219 A1 [0002]

Claims (10)

Spindle motor for driving a storage disk (( 34 ; 134 ; 234 ) of a disk drive ( 10 ; 110 ; 210 ; 310 . 410 ) and suitable for installation in a housing ( 14 ; 114 ; 214 ; 314 ; 16 ; 116 ; 216 ; 315 ) of an electronic device, the spindle motor comprising: a base plate; at least one stationary engine component mounted to the base plate, at least one movable engine component, a fluid dynamic bearing system for pivotally mounting the movable engine component relative to the stationary engine component, a cover disposed on a side opposite the base plate, and an electromagnetic drive system for rotary drive the movable motor component, characterized in that either the base plate or the cover, or the base plate and the cover as part of the housing ( 14 ; 114 ; 214 ; 314 ; 16 ; 116 ; 216 ; 315 ) of the electronic device are formed. Spindle motor according to claim 1, characterized in that it has a total height of at most 6 mm. Spindle motor according to one of claims 1 or 2, characterized in that the storage disk ( 34 ; 134 ; 234 ) is attached to the movable motor component and on the base plate write-read devices for writing and reading data are arranged on and from the storage disk. Spindle motor according to one of claims 1 to 3, characterized in that it is in the housing ( 14 ; 114 ; 214 ; 314 ; 16 ; 116 ; 216 ; 315 ) of the electronic device and is separately encapsulated and sealed by sealant. Spindle motor according to one of claims 1 to 4, characterized in that the fluid dynamic bearing system at least one fluid dynamic radial bearing ( 44 . 444 ; 46 . 446 ) and at least one fluid dynamic thrust bearing ( 48 . 448 ) as well as means for the magnetic preload of the thrust bearing in the form of at least one of the electromagnetic drive system independent permanent magnet ( 462 ) attached to the stationary engine component ( 428 ) immediately axially opposite the movable engine component ( 426 ) is arranged. Spindle motor according to claim 5, characterized in that between the permanent magnet ( 462 ) and the movable engine component ( 426 ) a narrow air gap ( 464 ) formed at the opening of a sealing gap ( 452 ) for sealing the fluid dynamic bearing adjacent. A disk drive having a spindle motor according to claims 1 to 6. Memory disk drive according to claim 7, characterized in that it is separately encapsulated in the housing ( 14 ; 114 ; 214 ; 314 ; 16 ; 116 ; 216 ; 315 ) of the electronic device is arranged. A disk drive according to claim 7, characterized in that it is a detachable unit on the housing ( 314 ; 315 ) of the electronic device is arranged. Electronic device with a disk drive, characterized in that parts of the housing ( 14 ; 114 ; 214 ; 314 ; 16 ; 116 ; 216 ; 315 ) of the electronic device as components of the disk drive ( 10 . 110 . 210 . 310 . 410 ) are formed.

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