KR100815516B1 - Spindle motor for hdd improved on construction of shaft, sleeve and base - Google Patents

Abstract

A spindle motor for an HDD(Hard Disk Drive) with improved structures of a shaft, a sleeve, and a base is provided to prevent separation of components due to external impact by increasing an assembly area of a shaft and a hub to improve assembly durability. A spindle motor for an HDD(Hard Disk Drive) includes a shaft(30), a sleeve(50), and a stopper(40). The shaft has an extended outer diameter unit to be coupled with a hub and has a recessed coupling groove with a predetermined inner diameter at a center of a lower part. The sleeve has a protruded ring bar formed along an outer side of a top surface vertically coupled with the shaft to partially insert the extended outer diameter unit of the shaft. The stopper is inserted into a bottom of an inner diameter unit of the sleeve to be in contact with a bottom surface of the shaft and has a coupling protrusion corresponding to the coupling groove of the shaft to be coupled with the coupling groove of the shaft.

Description

SPINDLE MOTOR FOR HDD IMPROVED ON CONSTRUCTION OF SHAFT, SLEEVE AND BASE}

1 is a view for briefly explaining the structure of a typical hard disk drive.

Figure 2 is a view for briefly explaining the structure of a conventional spindle motor for a hard disk drive.

3 is a view for conceptually explaining the structure of a spindle motor for a hard disk drive according to the present invention.

Figure 4 is a view for explaining in detail the spindle motor for a hard disk drive according to the present invention.

5 is a view for explaining a sleeve of the spindle motor for a hard disk drive according to the present invention.

6 is a view for explaining the coupling structure of the spindle motor for a hard disk drive according to the present invention.

*** Brief description of the reference numerals for the main parts of the drawings ***

1: platter 2: spindle motor

3: head 4: head arm

5: sppping motor

10: HUB 20: MAGNET

30: shaft 40: thrust bearing (conventional)

50: SLEEVE 60: Base

70: stator core 80: groove (GROOVE)

90: thrust plate 300: extension outer diameter

310: coupling groove 400: coupling jaw

500: projecting hospitality

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spindle motor for providing rotational force to a plurality of platters in a hard disk drive (HDD). In particular, a shaft and a sleeve may be used to prevent oil leakage of a hydrodynamic bearing in a rotating structure of a spindle motor. The present invention relates to a spindle motor for a hard disk drive having an improved structure.

In general, a hard disk drive refers to an auxiliary memory device that stores and reads data while rotating a disk-type aluminum substrate coated with a magnetic material. Due to their large capacity, they are widely used in small computers. In particular, a small hard disk drive is used in a personal computer (PC) because it is suitable for use in a personal computer. The capacity of the hard disk drive used in such a personal computer was basically 1GB level in the mid-1990s, and more than 16GB was generalized in the late 1990s. Globally, storage capacity is growing at 60% per year, with prices falling 12% per quarter.

Usually, the hard disk drive has a platter shaped like a record plate, and a concentric circle called a track is drawn thereon to record data electronically in the concentric circle. As shown in FIG. (1) consists of a stacked hard disk, spindle motor (2), head (3), head arm (4) and stepping motor (5).

The platter (1) is a thin coating of magnetic magnetic material on a metal disc, and due to the limitation of the capacity that can be recorded on one sheet, a high capacity hard disk uses several platters (1) depending on the size and number of hard disks. The size of is determined.

The spindle motor 2 rotates at a constant speed (for example, 3600 rpm, 5400 rpm, 7200 rpm) when power is supplied to a motor that rotates the platter 1, and at least one platter 1 is provided on the spindle shaft. It is designed to rotate at the same time. Controlling the correct rotation rate of this spindle motor (2) is of paramount importance for reliable reading and writing of data.

The head 3 also moves horizontally above and below the rotating platter 1 to read and write data to the platter 1.

In addition, the head arm 4 is an arm that allows the head 3 to move and adjusts the position of the head 3 under the command of the controller chip.

Finally, the stepping motor 5 is a driving force for moving the head 3 to the position of the platter 1, and the performance of the motor is good or bad, and the access time (hard disk drive places the data into the memory or Total time spent for transmission) is determined.

In particular, the spindle motor in the field to which the present invention is applied belongs to a brushless-DC motor and transmits a rotational force to the center of the platter which is the disc of the disk to rotate the platter. In addition to the hard disk drive, the main motor is widely used as a laser beam scanner motor for a laser printer, a motor for a floppy disk drive (FDD), and an optical disk drive motor such as a compact disk (CD) or a digital versatile disk (DVD). do.

In addition, recently, in a machine that requires a large capacity and high speed driving force such as the hard disk drive, in order to minimize noise and non-repetitive run out (NRRO), a fluid having a lower driving load (or driving friction) than a conventional ball bearing type is required. The trend is to use spindle motors with dynamic bearings.

Here, the hydrodynamic bearing is basically a thin oil film formed between the rotating body and the fixed body to support the rotating body with the pressure generated during rotation, so that the friction load is reduced because the rotating body and the fixed body do not contact each other. Therefore, a fluid dynamic bearing spindle motor (Fluid Dynamic Bearing Spindle Motor) is applied to maintain the shaft of the motor that rotates the disk only lubricating oil (: pressure to return to the center of the hydraulic pressure driven by the centrifugal force of the rotating shaft) It is distinguished from the ball bearing spindle motor which supports the shaft with steel balls.

In addition, in the case of the spindle motor to which the bearing is applied, noise and vibration (NRRO) are generated due to friction between the ball bearing and the shaft, and in particular, the vibration acts as an obstacle to increasing the track density of the hard disk. The hydrodynamic bearing has no metal friction on the basis of centrifugal force, and as the rotation speed increases, a sense of stability is increased, and thus, the hydrodynamic bearing is preferentially employed in a hard disk drive due to its low noise and vibration.

As such, the internal structure of the conventional spindle motor to which the hydrodynamic bearing is applied has a base 60, a sleeve 50, a coil wound stator core 70, a shaft 30, and a hub as shown in FIG. 10 and the magnet 20.

The spindle motor is fixed to the sleeve 50 is vertically coupled to the inside of the base 60 to form an appearance, and the stator core 70 is wound around the upper side of the base 60 is mounted, the sleeve 50 The shaft 30 is rotatably inserted through the inner center of the shaft. And the lower end of the shaft 30 is coupled to the disk-shaped thrust bearing 40 rotatably coupled with the shaft 30 and its lower end is shielded from the outside by a cover plate, the upper end of the shaft 30 is internal The cap-shaped hub 10 opened downward is coupled. In addition, a magnet 20 is attached to a position facing the stator core 70 inside the end of the hub 10, and an oil gap between the outer circumferential surface of the shaft 30 and the thrust bearing 40 and the sleeve 50. This oil gap is filled with fluid such as lubricating oil or grease.

Therefore, the hydrodynamic bearing spindle motor having the above structure has a hub 1 and a shaft coupled thereto by an electromagnetic repulsive force applied between the stator core 70 and the magnet 20 in which the coil is wound when an external power is applied. 30 rotates.

In addition, in the inner circumferential surface of the sleeve 50, a plurality of grooves 80 are formed in the shape of a herringbone or spiral, and when the shaft 30 rotates, the oil filled in the oil gap is pressurized. By moving to the center of the groove 90 by the gradient to generate the fluid dynamic pressure to support the shaft (30).

However, since the conventional spindle motor shown in FIG. 2 constitutes a dynamic bearing oil at the upper end portion and the inner diameter portion of the sleeve 50, oil leakage and splashing due to the centrifugal force and impact from the outside during rotation of the spindle motor are rotated. This may occur, and the assembly length of the hub 10 and the shaft 30 is short, so that it is difficult to secure the assembly strength of the hub 10 and the shaft 30 and is vulnerable to external shocks. There is a problem that causes an error.

Accordingly, the present invention has been made in view of the above problems, and provides a spindle motor for a hard disk drive that prevents oil leakage and scattering due to centrifugal force during rotation of the spindle motor and impact from the outside during rotation. There is this.

In addition, by increasing the assembly area of the shaft and the hub to improve the assembly durability to prevent the separation of parts due to external shocks to provide a hard disk drive spindle motor that can reduce the occurrence of errors in the hard disk drive have.

In order to achieve the above object, a spindle motor for a hard disk drive having an improved structure of a shaft, a sleeve, and a base of the present invention includes a hub 10 having a magnet 20 installed on an inner side thereof in a cap shape which is opened downward, and the hub. The shaft 30 coupled to one side to the center of the 10, having the oil gap so that the shaft 30 is rotatable and coupled to the shaft 30, radial for generating dynamic pressure on the inner circumferential surface and the upper surface A sleeve 50 in which a directional dynamic pressure generating groove 81 and an axial dynamic pressure generating groove 82 are formed at a predetermined position, a base 60 for fixing the sleeve 50, and the magnet 20; In the spindle motor for a hard disk drive comprising a stator core (70) wound around a coil coupled to the base (60) facing each other, and a thrust plate (90) for closing one side of the sleeve (50), the shaft (30). Its upper part Form an expansion outer diameter portion 300 extended by a predetermined size than the outer diameter of the center side to engage with the hub, and form a coupling groove 310 recessed to have a predetermined inner diameter at the center of the lower surface; The sleeve 50 forms a protruding annulus 500 protruding to a predetermined size so as to insert a portion of the extended outer diameter portion 300 of the shaft 30 along the outer side of the upper surface vertically coupled with the shaft 30. and; It has a predetermined outer diameter and size and is inserted into the lower side of the inner diameter of the sleeve 50 to be in contact with the lower surface of the shaft 30, and has a size corresponding to the engaging groove 310 formed in the lower portion of the shaft 30 The stopper 40 is inserted into and coupled to the coupling groove 310 of the shaft 30 by forming the coupling jaw 400 at the center side.

Here, the extended outer diameter portion 300 of the shaft 30 is characterized in that the oblique processing in the outward direction a portion close to the inner diameter portion of the protruding annulus 500 of the sleeve (50).

In addition, the base 60 is formed so that the upper portion of the inner diameter portion close to the outer diameter portion of the sleeve 50 is recessed inwardly.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification. In addition, when a part is said to "include" a certain component, which means that it may further include other components, except to exclude other components unless otherwise stated.

Now, a spindle motor for a hard disk drive according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The following terms are defined in consideration of functions in the present invention, and are intended to be used by users, operators, or customs. It may vary. Therefore, the definition should be made based on the contents throughout the present specification.

3 is a view for conceptually explaining the structure of a spindle motor for a hard disk according to the present invention, Figure 4 is a view for explaining in detail the spindle motor for a hard disk drive according to the present invention, Figure 5 is the present invention FIG. 6 is a view illustrating a sleeve of a spindle motor for a hard disk drive according to the present invention, and FIG. 6 is a view for explaining a coupling structure of the spindle motor for a hard disk drive according to the present invention.

As shown in the figure, the configuration of the spindle motor according to the present invention includes a rotating part consisting of a hub 10 to which a shaft 30 and a magnet 20 are coupled, a base 60, a sleeve 50, and a coil stator core. It consists of a fixed portion consisting of 70 and the thrust plate (90). That is, the hub 10 coupled thereto is rotated about the shaft 30 vertically coupled to the base 60.

To describe the rotation part and the fixing part constituting the spindle motor more,

First, the rotating part is formed of a hub 10 in which the magnet 20 is installed on the inner side in the shape of a cap open to the rear and a shaft 30 to which one side is coupled to the center of the hub 10.

On the other hand, the fixing part has a predetermined oil gap so that the shaft 30 is rotatable, coupled with the shaft 30, one side is closed by the thrust plate 90 and the inner diameter portion to generate a radial pressure in the radial direction Radial directional dynamic pressure generating grooves 81 are formed in a predetermined position in the sleeve 50 and the base 60 to fix the sleeve 50 and the base 20 to face the magnet 20. Coil coupled to the) is made of a stator core (70) wound.

In this case, the radial dynamic pressure generating groove 81 for generating dynamic pressure in the radial direction may be formed in the inner diameter portion of the sleeve 50, but is not limited thereto, and the shaft facing the sleeve 50 may be formed. Radial directional dynamic pressure generating grooves 81 may also be formed in the outer diameter portion of 30.

On the other hand, the spindle motor for a hard disk drive according to the present invention does not exist a thrust bearing used in the conventional spindle motor, the stopper 40 is inserted into the lower inner diameter of the sleeve 50 is fixed to the lower end of the shaft 30 (40) ) To support the shaft 30 and to provide stable rotation of the rotating part.

In addition, since the thrust bearing is not used as described above, the oil holding space is largely secured in the space occupied by the conventional thrust bearing, so that the problem caused by the oil can be solved in the reliability test, and the dynamic pressure in the radial direction is reduced. In order to increase the inner diameter portion of the sleeve 50 or the outer diameter portion of the shaft 30 adjacent thereto, a feature that can further secure the processing area of the radial directional dynamic pressure groove 81 is generated.

Therefore, the dynamic pressure in the radial direction is further increased to stably support the shaft, thereby improving the stable characteristics of the product and eliminating the difficulty of directionally assembling the groove according to the processing direction of the groove formed in the thrust bearing. have.

Referring to the operation structure of the spindle motor according to the present invention, the magnet 20 is coupled to the inner surface of the hub 10 of the cap-shaped hub 10 of the spindle motor for the hard disk drive according to the present invention, to the base 60 The hub 10 is rotated by the electric repulsive force formed by the current and voltage applied to the stator core 70 wound by the coupled coil, and the shaft 30 coupled thereto is rotated together. At this time, by using the hydrodynamic bearing as a bearing means for smooth and stable rotation of the hub 10, the noise and vibration as well as the friction and resistance of the object during the rotational movement significantly reduced.

At this time, the shaft 30, the sleeve 50, the hub 10 and the base 10 constituting the hydrodynamic bearing has a structure as shown in Figs.

The shaft 30 integrally coupled to one side of the hub 10 vertically is inserted into and coupled to the sleeve 50 to form an oil gap, which is a space into which oil is injected.

Here, since the upper portion of the shaft 30 is formed to expand the outer diameter portion 300 extended by a predetermined size than the outer diameter of the center side and coupled with the hub 10, the assembly of the hub 10 and the shaft 30 By increasing the area to improve the assembly strength to prevent the departure of the component due to external impact, there is a feature that can solve the problem of securing the assembly strength in the conventional coupling of the shaft and the hub.

In addition, the shaft 30 forms a coupling groove 310 recessed to have a predetermined inner diameter at the center of the lower portion thereof, and the coupling groove 310 has a stopper 40 to support and fix the shaft 30. ) Will combine.

On the other hand, by the oil filled in the oil gap, the rotating part rotates together with the hub 10 in the sleeve 50 coupled to the base 60. At this time, grooves for generating dynamic pressure in the radial direction of the rotating part are respectively formed at the upper end and the lower end of the inner circumferential surface of the sleeve 50, or are formed at the upper end and the lower end of the outer circumferential surface of the shaft 30, respectively.

In addition, the shaft 30 has a predetermined size so that a portion of the extended outer diameter portion 300 of the shaft 30 may be inserted along the outer side of the upper surface of the sleeve 50 to which the shaft 30 is inserted and vertically coupled. Protruding protrusions 500 will be formed.

Here, the groove for generating dynamic pressure in the axial direction is formed on the lower surface of the extended outer diameter portion 300 of the shaft 30 or on the upper surface of the sleeve 50 in contact with the groove.

In other words, Figure 5 is a view showing a sleeve 50 according to the present invention, in this case, the machining position of the axial dynamic pressure groove (82) and radial directional dynamic pressure groove (81) providing dynamic pressure Is not limited as shown in the drawing, the axial dynamic pressure groove 82 is formed on the upper end of the sleeve 50 or on the lower end surface of the extended outer diameter portion 300 of the shaft 30 facing it. Radial directional dynamic pressure groove 81 is formed on the inner diameter of the sleeve 50 or on the outer diameter surface of the shaft 30 facing it.

In addition, the axial dynamic pressure generating groove 82 and the radial directional dynamic pressure generating groove 81 are preferably formed of a herring-bone or spiral pattern.

As such, the present invention does not use the conventionally used thrust bearings, so it is not necessary to check the assembly direction by the grooves processed in the thrust bearings, thus eliminating the difficulty of directionally assembling the spindle motor. In such a case, the protruding annulus 500 is formed on the upper surface thereof to prevent scattering of oil due to centrifugal force and impact from the outside during rotation of the spindle motor.

In addition, in order to improve the assembly durability of the hub 10 and the shaft 30, the present invention further improves the assembly durability by forming an extended outer diameter portion 300 having an outer diameter larger than the center side of the upper portion of the shaft 30. Another feature.

FIG. 6 is a view for explaining a coupling structure of the spindle motor. As shown in FIG. 6, the hub 10 has a downwardly open cap shape. The magnet 20 is provided to provide an electric repulsion force, and the shaft 30 having the extension outer diameter part 300 is coupled to the open side of the hub 10. In addition, the upper side and the lower side is open and the cylindrical shape having a predetermined inner diameter, the upper surface is fixed to the sleeve 50 is formed with a protruding annulus 500 is fixed to the inner diameter of the sleeve 50 shaft 30 is a rotation axis ) Is mounted with a predetermined oil gap so as to be rotatable.

At this time, the shaft 30 forms a coupling groove 310 recessed to have a predetermined inner diameter at the center of the upper surface thereof, and the stopper 40 inserted into the coupling groove 310 to fix the shaft 30. ) Has a predetermined outer diameter and size and is inserted into the lower side of the inner diameter of the sleeve 50 so as to be in contact with the lower surface of the shaft 30 and have a size corresponding to the coupling groove 310 formed in the lower portion of the shaft 30. The coupling jaw 400 having the center is formed to be inserted into the coupling groove 310 of the shaft 30.

In addition, a thrust plate 90 for closing the other open side of the sleeve 50 is coupled to the lowermost end of the sleeve 50.

On the other hand, the base 60 according to the present invention has a corresponding inner diameter so that the sleeve 50 can be inserted and fixed, the coil for providing an electrical repulsive force to the magnet 20 coupled to the hub 10 The wound stator core 70 is provided inside.

In addition, the base 60 is characterized in that the upper portion of the inner diameter portion which is close to the outer diameter portion of the sleeve 50 is formed to be recessed inward, which is to prevent the scattering of oil by centrifugal force during rotation of the spindle motor In order to prevent the leakage of oil through the site of depression of the base 60 is prevented primarily in the protruding annulus 500 of the sleeve 50.

On the other hand, as shown in Figure 4 when looking at the extension outer diameter portion 300 of the shaft 30 in accordance with the present invention, a part of which is coupled to the hub 10 and the other part of the projection 50 of the sleeve 50 It is inserted into the inner diameter portion of the 500, the oblique processing in the outward direction of the portion that is close to the inner diameter portion of the protrusion annular 500 (A) may be another feature of the present invention.

This is to prevent the oil leakage, surface tension is increased than when processing in the conventional plane, when the spindle motor is not rotated due to the increase in surface tension to form a thin oil film can prevent the oil leakage. .

As described above, in the present invention, the structure of the shaft 30, the sleeve 50, and the base 60 is improved to prevent the oil from scattering and leakage during the rotation and non-rotation of the spindle motor, thereby improving the assembly durability. Overall, there is a feature that can reduce the error occurrence of the hard disk drive.

Although the present invention has been shown and described with reference to certain preferred embodiments, the present invention is not limited to the above-described embodiments, and the general knowledge in the technical field to which the present invention pertains does not fall within the spirit of the present invention. Various changes and modifications may be made by the possessor.

The spindle motor for a hard disk drive having an improved structure of the shaft, the sleeve and the base of the present invention having the configuration as described above improves the structure of the shaft, the sleeve and the base to prevent the leakage of oil constituting the dynamic bearing during rotation of the spindle motor. This prevents double contamination and prevents contamination of the spindle motor, and expands the outer diameter of the upper side of the shaft to increase the engagement area with the hub, thereby improving assembly durability due to external shocks, resulting in hard disk drive error. An effect that can be reduced occurs.

In addition, by removing the thrust bearing and supporting the shaft by the stopper, it is possible to secure the processing area of the radial dynamic pressure generating groove, and to increase the radial dynamic pressure to stably support the shaft. Also in the cooking process, since the difficulty of directionally assembling according to the processing direction of the groove formed in the conventional thrust bearing can be eliminated, there is an effect of improving the assembly method and assembly.

Claims (3)

Hub 10 is provided with a magnet 20 on the inner side in the form of a cap open downward, the shaft 30 is coupled to one side to the center of the hub 10, the oil gap so that the shaft 30 is rotatable A sleeve in which a radial direction dynamic pressure generating groove 81 and an axial direction dynamic pressure generating groove 82 are formed at a predetermined position to be coupled to the shaft 30 and to generate dynamic pressure on the inner circumferential surface and the upper surface thereof. 50, a base 60 fixing the sleeve 50, a stator core 70 wound around a coil coupled to the base 60 so as to face the magnet 20, and one side of the sleeve 50. In the spindle motor for a hard disk drive consisting of a closed thrust plate (90), The shaft 30 is coupled to the hub by forming an extended outer diameter portion 300 whose upper portion is extended by a predetermined size than the outer diameter of the center side, and the coupling groove 310 recessed to have a predetermined inner diameter at the center of the lower surface. ); The sleeve 50 forms a protruding annulus 500 protruding to a predetermined size so as to insert a portion of the extended outer diameter portion 300 of the shaft 30 along the outer side of the upper surface vertically coupled with the shaft 30. and; Coupling having a predetermined outer diameter and size and is inserted into the lower side of the inner diameter of the sleeve 50 in contact with the lower surface of the shaft 30, the coupling having a size corresponding to the coupling groove 310 formed in the lower portion of the shaft 30 Spindle motor for a hard disk drive, characterized in that it further comprises; a stopper (40) formed at the center of the jaw (400) and inserted into the coupling groove 310 of the shaft (30). According to claim 1, wherein the extension outer diameter portion 300 of the shaft 30 Hard disk drive spindle motor, characterized in that the oblique processing in the outward direction of the portion close to the inner diameter of the protruding annulus 500 of the sleeve (50). The method of claim 1. The base 60 is The upper portion of the inner diameter portion in contact with the outer diameter portion of the sleeve 50 is formed to be recessed inwardly; a spindle motor for a hard disk drive, characterized in that.

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