DE3135385A1 - Disc storage unit - Google Patents

Abstract

Disc storage unit for receiving at least one storage disk provided with a central opening. The disc storage unit is provided with an external-rotor drive motor, which has a rotor housing which is mounted rotatably with respect to a stator by means of a shaft in a bearing system and onto which the storage disc can be placed for the purpose of being driven along with the rotor housing. At least the part of the rotor housing receiving the storage disc is made of a non-ferromagnetic material. It bears the shaft directly or via a hub. Protruding into the storage disc receiving part of the rotor housing is a screening box of ferromagnetic material, which is connected in a rotationally fixed manner to the said housing, encloses the magnetically active part of the drive motor at its circumference and its one end face and the base of which has a central opening, the edge of which lies directly radially alongside the shaft or the parts of the drive motor carrying or bearing the shaft. <IMAGE>

Description

Disk storage

(Addition to application P 31 08 204.1) The invention relates to a Disk storage for receiving at least one provided with a central opening Storage disk, with an external rotor drive motor that has a shaft in one Has bearing system with respect to a stator rotatably mounted rotor housing that the storage disk can be placed for the purpose of being taken through the rotor housing, according to Patent (patent application P 31 08 204.1).

The main patent (patent application P 31 08 204.1), on its c content Reference is made in full to avoid repetition, has a disk storage for receiving at least one central opening Storage disk to the subject in which the. ~ Drive motor at least partially extends through the central opening of the storage disk coaxially and means for non-rotatable connection of the Storage disk with the rotor of the drive motor are provided.

The present invention is based on the object of the structure a disk storage according to the main patent to further simplify and its mode of operation to improve. In particular, the storage disk should protect against undesired influences be safely protected by the magnetically active parts of the drive motor. Of a particularly space-saving and robust structure of the drive motor is also intended can be achieved.

The solution to this problem is based on a disk storage of the type mentioned according to the invention that at least the storage disk receiving part of the rotor housing made of a non-ferromagnetic material is and the shaft carries directly or via a hub, as well as that in the storage disk receiving part of the rotor housing a magnetic shielding pot connected to it in a rotationally fixed manner made of ferromagnetic material protrudes, which is the magnetically active part of the Drive motor encloses on its circumference and its one end face and its Bottom has a central opening, the edge of which is immediately radially adjacent to the shaft or the parts of the drive motor which carry or support the shaft lies. A rotor housing constructed in this way is easy to manufacture and it protects the sensitive storage disks, especially magnetic hard disk drives, effective against from the magnetically active parts of the drive motor outgoing magnetic leakage flux. In the case of the shielding pot, it can preferably be act to a deep-drawn part, while the storage plate receiving part of the Rotor housing can be made of light metal in the die casting process.

Is the drive motor in the manner explained in the main patent as Brushless DC motor with permanent magnet rotor, is used in further embodiment of the invention a printed circuit board with at least a rotary position detector and, if necessary, further components for the control and / or control of the drive motor on the opposite to the bottom of the shielding pot Side of the stator arranged.

This ensures that the rotational position detector and any others Circuit components of the magnetic shield are not in the way.

Further advantageous refinements of the invention emerge from the subclaims. The feature of claim 3 contributes to a compact design of the disk storage. In the case of disk storage devices of the type under consideration here The requirements placed on the concentricity of the storage disks are extremely high.

As a result, the disk receiving part usually has to be ground or machined to size in another appropriate way. By the Feature of claim 4 is the necessary processing on a relatively small Part of the peripheral surface of the storage disk receiving part limited. That characteristic of claim 5 allows a trouble-free installation of a storage disk on the shoulder of the disk receiving part.

With the development according to claim 6, a robust precision bearing is achieved possible. With the feature of claim 7, the available axial length in Direction used to maximize the axial distance of the bearings. The feature of the Claim 8 allows particularly large axial bearing distances in cases where the axial installation space between the mounting flange and the end face of the storage disk receiving part is limited, but installation space is available on the other side of the mounting flange stands. Claims 9 and 10 and 11 have two alternative solutions as their subject matter, which lead to particularly small radial runouts of the rotor. With the characteristics of the Claims 12 and 13 a space-saving accommodation of the circuit board is achieved. The training according to claim 14 is particularly recommended for solutions in which it depends on an extremely flat design.

Further features and advantages of the invention emerge from the following Explanation of preferred exemplary embodiments in connection with the enclosed Drawings. They show: FIG. 1 a vertical partial section through a first Embodiment of the invention along the line I-I, Fig. 2 a Top view of the arrangement according to FIG. 13, FIG. 3 shows a section through a modified one Embodiment of the invention with an extended bearing tube and FIG. 4 shows a section by a further modified embodiment of the invention.

The illustrated in Fig. 1, executed in an extremely flat design Disk drive has a brushless DC motor 45 with one fixedly connected to a rotor shaft 46 and concentric to the rotor shaft 46 Rotor housing 47 is provided. A laminated stator core 48, which has a stator winding 49 carries is pushed onto a bearing tube 50. The rotor shaft 46 is in the bearing tube 50 by means of two bearings 52, 53 rotatably supported by retaining rings 54 axially are kept at a distance from each other. A plate spring 55 is supported on the underside of the bearing 53 and a locking ring 56 seated on the rotor shaft 46, whereby the bearings 52, 53 are axially braced against one another. The bearings 52, 53 are at glued into the bearing tube 50 during assembly. The bearing tube 50 forms together with a mounting flange 24 is a one-piece die-cast part.

The rotor housing 47 consists of a storage disk receiving part 25 and a shielding pot 26, which are connected to one another, for example riveted, are. The disk receiving part 25 is made of non-ferromagnetic Material, preferably light metal, manufactured. The rotor shaft 46 is in a central opening of the storage disk receiving part 25 pressed in. Instead, the wave can go into the The receiving part can also be cast.

The shielding pot 26 consists of ferromagnetic material; he can in particular be designed as a soft iron deep-drawn part.

On the radially opposite inner surface of the stator lamination 48 Shielding pot 26 are a plurality of permanent magnet segments or a one-piece Permanent magnet 69 attached. The permanent magnet 69 is preferably composed of a mixture of hard ferrite, e.g.

Barium ferrite, and elastic material. So it's one so-called rubber magnets. This is trapezoidal or approximately over the pole pitch trapezoidal magnetized radially with a relatively small pole gap. The shielding pot 26 at the same time forms the magnetic return path for the magnet 69. The shielding pot 26 encloses the magnetically active part 48, 49, 69 of the drive motor 45 at its Circumference and its one end face.

In which the shape of the end windings 27 of the stator winding 49 is adapted At the bottom 28 of the shielding cup 26 is a central opening 29, the edge of which is directly radially adjacent to the circumferential surface of the bearing tube 50 is. The shielding pot prevents in this way particularly effective for the leakage of magnetic leakage flux Outside of the storage disk receiving part 25.

The storage disk receiving part 25 has two stair-like paragraphs 74, 75, each of which has several, in the illustrated Embodiment six, arranged distributed in the circumferential direction radially protruding Bearing bars 79 resp.

80 wear. The bearing webs 79, 80 are corresponding on their outside the inner diameter of the hard disk to be placed on the receiving part 25 Machined to size, especially ground. The heels 74, 75 form shoulders 81, 82, each with a ring-shaped Grooves 83 and 84 are provided. This ensures that the bearing bars 79, 80 pushed-on storage disks, each with a different opening diameter lean against the shoulders 81, 82 neatly.

The mounting flange 24 is equipped with a recess 85, in which houses a printed circuit board 86. The circuit board 86 carries a rotational position detector, for example in the form of a Hall IC, and optionally further circuit components for the control and / or regulation of the drive motor 45. The Hall IC 63 extends from the printed circuit board 86 in the axial direction up to the immediate vicinity of the stator core 48. The permanent magnet 6S is over the stator core 48 axially in the direction of the circuit board 86 up to the partial axial overlap with the Hall IC 63. In this way, the Hall IC 63 detects or, alternatively, another magnetic field-dependent semiconductor component sets the rotary position of the rotor of the drive motor 45.

The two bearings 52, 53 are approximately in this embodiment the same axial distance from the axial center of the permanent magnet 69 and the stator core 48 is arranged.

The storage drive is attached to a partition wall by means of the mounting flange 24 of the hard disk storage arranged, which is used to accommodate the storage disks separates a certain room of the highest purity from the rest of the interior of the device. From the warehouse 52 and from parts of the drive motor 45 emerging dirt particles, grease vapors or the like are through labyrinth seals 90, 91 at a transition into the Storage disk receiving space prevented.

The labyrinth seal 90 is obtained in that the mounting flange 24 bending end of the bearing tube 50 in an annular groove 87 on the end face of the storage disk receiving part 25 protrudes to form sealing gaps. Similarly, take up education the labyrinth seal 91 the end of the shielding pot 26 in an annular groove 88 of the mounting flange 24 a.

The labyrinth seals 90, 91 are preferably in the main patent measured in the manner described in more detail.

The embodiment according to FIG. 3 differs from the arrangement according to Figures 1 and 2 in that the storage disks with the same opening inside diameter be placed on bearing webs 79 of a storage disk receiving part 89, which the magnetic shielding pot 26 surrounds most of its axial dimension. In other words, the magnetically active parts 48, 49, 69 of the drive motor 45 come partially within the storage disk center opening. In the storage disk receiving part 89 is a sleeve-shaped hub 98 pressed or cast, in turn the rotor shaft 46 pressed in is. The edge of the central opening 29 in the bottom 28 of the shielding pot 26 extends to a section receiving the hub 98 99 of the receiving part 89.

The bearing tube 50 stands on the one facing away from the stator core 48 Side of the mounting flange 100 in the axial direction. This makes a special Achieve a large axial distance between the two bearings 52, 53. The bearing 52 is seated in the axial direction near the axial center of permanent magnet 69 and stator laminated core 46. The other Bearing 53 has an axial distance from bearing 52 that is equal to or greater than that twice the bearing outer diameter.

To the operational safety of the disk storage disruptive electrical The rotor, which rotates at high speed during operation, must not be charged the rotor shaft 46 via a bearing ball 78 and a spring contact, not shown expediently electrically connected to the equipment chassis. One the rotary position detector 63 and possibly further electronic components carrying printed circuit board 101 is on the end of a spacer ring facing the mounting flange 100 102 supported between the mounting flange 100 and the stator core 48 sits. In the mounting flange 100 is an aligned with the annular circuit board 101 Annular groove 103 incorporated. The annular groove 103 creates space for receiving the at the Underside of the circuit board 101 protruding wire ends and soldered connections.

Fig. 4 shows an embodiment in which the disk receiving part 105 is extended in the axial direction by an im Compared to the arrangement to be able to store a larger number of storage disks according to FIG. 3. The bearing tube 50 is axially extended accordingly to take into account the existing installation space to use the maximum axial distance of the bearings 52, 53. The bearing tube 50 engages with its end remote from the mounting flange 106 the receiving part 105 with of the shaft 46 connecting hub 98 to form a labyrinth seal 107. The Edge of the central opening 29 of the shielding pot 26 is close to the outside of the Bearing tube 50 brought up. The shielding pot 26 dips into with its free end a recess 108 of the mounting flange 106.

This creates a further labyrinth seal 109. Otherwise, corresponds this AusfUhrungsform the previously explained arrangements.

It is understood that individual design features of the described Embodiments are interchangeable.

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Claims (14)

Claims disk storage for receiving at least one with one Central opening provided storage disk, with an external rotor drive motor, the one that is rotatably mounted in relation to a stator in a bearing system via a shaft Has rotor housing on which the storage disk for the purpose of being taken through the rotor housing can be attached, according to patent (P 31 08 204.1), characterized in that at least the storage disk receiving part (25, 89, 105) of the tube housing (47) from a nods-ferromagnetic material is made and the shaft (46) directly or via a hub (98) and that in the storage disk receiving part of the rotor housing a magnetic shielding pot (26) made of ferromagnetic and rotatably connected to this Material protrudes which forms the magnetically active part (48, 49, 69) of the drive motor (45) encloses on its circumference and its one end face and its bottom (28) has a central opening (29), the edge of which is immediately radially adjacent the Shaft or the parts (50, 98, 99) of the drive motor carrying or bearing the shaft lies. 2. Disk storage according to claim 1, wherein the drive motor as Brushless DC motor is designed with a permanent magnet rotor, thereby characterized in that a printed circuit board (86, 101) with at least one rotational position detector (63) and, if necessary, further components for the control and / or regulation of the drive motor (45) on the one opposite the bottom (28) of the shielding pot (26) Side of the stator (48, 49) is arranged. 3. Disk storage device according to claim 2, characterized in that as Rotation position detector (63) a magnetic field-dependent semiconductor component or Semiconductor IC is provided, which starts from the printed circuit board (86, 101) axially extends to the vicinity of the stator iron core (48), and that the rotor magnet (69) in Axial direction over the stator iron core in the direction of the circuit board up to at least partial axial overlap with the rotational position detector protrudes. 4. Disk storage according to one of the preceding claims, characterized characterized in that the storage disk receiving part (25, 89, T05) of the rotor housing (47) on its circumferential surface which can be brought into engagement with the central opening of the storage disk several distributed in the circumferential direction, radially protruding, bearing webs (79, 80) machined to size for the storage disk. 5. Disk storage according to claim 4, characterized in that the Storage disk receiving part (25, 89, 105) in the axial direction adjacent to the one End of the bearing webs (79, 80) a radially outwardly projecting shoulder (81, 82), which is provided with an annular groove (83, 84) is provided. 6. Disk storage according to one of the preceding claims, characterized characterized in that the stator (48, 49) with one on the bottom (28) of the shielding pot (26) axially opposite side of the stator iron core (48) lying radially extending mounting flange (24, 100, 106) is connected, one of which is the stator iron core (48) carrying bearing tube (50) goes out, in each of its two axial ends a Bearing (52, 53) for the shaft (46) is housed. 7. Disk storage device according to claim 6, characterized in that the Storage tube (50) with the central opening (29) in the bottom (28) of the shielding pot (26) Game interspersed. 8. Disk storage device according to claim 6 or 7, characterized in that that the bearing tube (50) on the remote from the stator iron core (48) side of the Mounting flange (100) protrudes in the axial direction. 9. Disk storage device according to claims 6 and 8, characterized in that that the one bearing (52) in the axial direction in the vicinity of the axial center of the rotor magnet (69) and stator iron core (48) is seated. 10. Disk storage device according to claim 8 or 9, characterized in that that the axial distance between the two bearings (52, 53) is equal to or greater than twice Bearing outer diameter is. 11. Disk storage device according to claim 6 or 7, characterized in that that the two bearings (52, 53) at approximately the same axial distance from the axial center the rotor magnet (69) and the stator iron core (48) are arranged. 12. Disk storage device according to one of claims 6 to 11, characterized in that that the circuit board (86, 101) is immediately adjacent within or in the axial direction a recess (85, 103) of the mounting flange (24, 100, 106) is arranged, which the bearing tube (50) engages around at least part of its circumference. 13. Disk storage device according to one of claims 6 to 12, characterized in that that the circuit board (101) on the end facing the mounting flange of an between the mounting flange and the stator iron core (48) seated spacer ring (102) is supported. 14. Disk storage according to one of the preceding claims, characterized characterized in that the shape of the bottom (28) of the shielding pot (26) to the dem Bottom adjacent winding heads (27) of the stator winding (49) is adapted.