KR100314092B1 - Optical flying head assembly - Google Patents

Abstract

A floating optical head assembly is disclosed.

The disclosed optical head assembly comprises: a suspension; A resilient piece that is fixed to the suspension in a cantilever form and is supported with a predetermined elasticity with respect to the suspension; A lens fixed to the distal end of the elastic piece; A slider which is located at the bottom of the lens and whose bearing surface is provided at the bottom of the lens; Equipped. According to this structure, the structure of the head can be simplified. In addition, since the portion in which the floating force is generated and the head portion including the lens is provided on the coaxial, it is easy to adjust the floating force and also stably maintain the floating state. In particular, the mass of the slider can be reduced and downsized, so that operation is possible under a small lift force, and since the lens is in contact with the media through the slide, the collision or contact between the media and the head is particularly prevented.

Description

Floating optical head assembly

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floating optical head assembly, and more particularly, to a gimbal assembly for a floating optical recording head which prevents contact between the head and the media and easily adjusts the effective height of the injury.

6mg mass, 2.0x1.6x0.425 (WxHxD) mm, in order to maintain the current height of 40nm flying height in the head and disk of HDD (Hard Disc Drive) adopting floating magnetic head Suspension suitable for generating the required seek speed for these masses, employing a Nano Slider of ³ and a mass of 1 mg, a Pico Slider of 1.2x1.0x0.3 (WxHxD) mm ³ There is a trend to adopt.

1 is a schematic plan view of a conventional gimbal assembly applied to the HDD, Figure 2 is a side view thereof.

1 and 2, the elastic piece 2 is coupled to one end of the suspension 1, and the slider 3 is coupled to the front end of the elastic piece 2. One end of the elastic piece 2 is fixed to the suspension 1, and the portion of the side on which the slider 3 is installed is in contact with a dimple formed on the bottom surface of the suspension 1, that is, the protrusion 1a. It is. Accordingly, the elastic piece 2 is fixed to the load beam 1 in the form of a cantilever lever, while the other end thereof is pressurized and deformed by the protrusion 1a to the protrusion 1a at a constant pressure. Contacting. Therefore, since the elastic piece 2 is provided with respect to the suspension 1 with appropriate elasticity, the elastic piece 2 withstands the mass of the slider 3 provided at its tip.

The structure of the gimbal assembly is also applied to a gimbal assembly for a near-field optical recording (NFR) drive to support an optical pickup head having a mass of about 30 mg.

3 is a schematic plan view of a conventional gimbal assembly for an NFR drive, and FIG. 4 is a side view thereof.

3 and 4, the elastic piece 12 is fixed to one end of the suspension 11, and the slider 13 is fixed to the elastic piece 12. The objective lens 14 and the SIL (Solid Immersion Lens) 15 are fixed to the upper and lower ends of the slider 13. The resilient piece 12 is fixed to the suspension 11 in a cantilever form by a plurality of welding points on the suspension 11, and the other end thereof is a protrusion 11a formed to protrude downwardly at the distal end of the suspension 11. Is in elastic contact with

In the conventional gimbal assembly having the structure as described above is to obtain a floating force to the media by the bearing surface (13a) of the slider 13, the bearing surface (13a) to obtain the floating force is a constant SIL lens 15 At a distance, the bearing surface 13a is positioned closer to the hinge of the support point of the suspension. The assembly of such a structure secures a space above the objective lens 14 through which the laser is scanned, and constrains translational freedom, which is a necessary function of the optical pickup head, and applies downward force for stable injury without restraining rotational freedom. In order to secure the position of the protrusion 11a, which is a supporting point necessary to give), the form of the gimbal assembly of FIGS. 1 to 2 described above is used as it is. However, this structure causes stability problems due to the addition of a relatively large slider mass during track seek of the media, which may cause a problem of collision or contact with the media. This stability problem is because the head including the objective lens and the SIL is located farther from the hinge than the slider, so that the load on the elastic piece due to the change in the mass of the head is greatly increased.

It is a first object of the present invention to provide a floating optical head assembly having a structure in which a structure can be easily and stably floated.

It is a second object of the present invention to provide a floating optical head assembly capable of effectively preventing contact between the head and the media.

It is a third object of the present invention to provide a floating optical head assembly capable of effectively suppressing accumulation of foreign matter on a slider.

1 is a schematic plan view of a conventional floating head assembly applied to a HDD.

FIG. 2 is a side view of the conventional floating head assembly shown in FIG. 1.

3 is a schematic plan view of an optical head assembly for a conventional NFR drive.

4 is a side view of the optical head assembly for the conventional NFR drive shown in FIG.

5 is a schematic plan view of a floating optical head assembly according to the present invention.

6 is a side view of the floating optical head assembly according to the present invention shown in FIG.

7 is a plan view of a lens applied to the floating optical head assembly according to the present invention shown in FIG.

8 is an excerpt of the head portion of the floating optical head assembly according to the present invention shown in FIG.

9 is a cross-sectional view showing the structure of a lens of the floating optical head assembly according to the present invention shown in FIG.

FIG. 10 is an excerpt bottom view of a slide of a gimbal assembly for a floating optical recording head according to the present invention shown in FIG.

FIG. 11 is an excerpt bottom view of another embodiment of a slide of the floating optical head assembly according to the present invention shown in FIG.

According to the present invention for achieving the above object, the suspension; A resilient piece fixed to the suspension in a cantilevered form and supported with a predetermined elasticity with respect to the suspension; A lens fixed to the distal end of the elastic piece; A slider which is located at the bottom of the lens and whose bearing surface is provided at the bottom of the lens; A floating optical head assembly is provided.

In addition, according to the present invention in order to achieve the above object, a suspension provided with a protrusion on one side of the front end; A resilient piece fixed to the suspension in the form of a cantilever and in contact with a predetermined elasticity with respect to the protrusion of the suspension; A lens fixed to the distal end of the elastic piece; A slider which is located at the bottom of the lens and has a bearing surface for the media at its bottom and a coaxial light transmission area for the lens; A floating optical head assembly is provided.

In the gimbal assembly of the present invention, the lens is provided with a light transmission recess concave with a predetermined curvature in the central portion of one side, the light transmission region corresponding to the light transmission groove is provided on the other side, the light Surfaces other than the transmission groove and the light transmission region are preferably formed to form a reflective layer.

One side of the lens on which the light transmitting groove is formed is preferably a hemispherical shape having a predetermined curvature, and the other side of the lens is substantially planar.

The through-hole having a predetermined diameter coaxial with the optical axis of the lens is formed at the distal end of the resilient piece on which the lens is mounted, and the flange is formed around the lens in contact with the periphery of the through hole provided at the distal end of the resilient piece. desirable.

The bottom of the slider is provided with a bearing surface located opposite to the rotational direction of the media, in particular, the bearing surface is preferably formed in a V-shape in the center portion.

Hereinafter, preferred embodiments of the floating optical head assembly of the present invention will be described in detail with reference to the accompanying drawings.

5 is a schematic plan view of a floating optical head assembly according to the present invention, and FIG. 6 is a side view thereof.

5 and 6, the other end of the suspension 110 having the hinge part or the fixing part 111 provided at one end thereof is fixed in a cantilever shape by a plurality of welding points 113 of the elastic piece 120. The front end of the elastic piece 120 is formed with a through hole 121 to which the lens 140 to be described later is mounted. The other end of the suspension 110 extends close to the through hole 121 of the elastic piece 120, and the elastic piece 120 is contacted with a predetermined pressure on the bottom surface of the tip portion corresponding to the elastic surface. The protrusion 112 is formed. Therefore, the elastic piece 120 is fixed with a constant elasticity with respect to the protrusion 112 with respect to the suspension (110).

The lens 140 and the slider 130 are sequentially fixed to the front end portion of the elastic piece 120, that is, the lower portion of the through hole 121. As shown in FIG. 7, a flange 141 is formed around the lens 140 in contact with a bottom surface of the periphery of the through hole 121 of the elastic piece 120. A concave portion 143 having a predetermined curvature is formed in the center of the upper surface 142 of the lens 140 having a predetermined curvature. A light passing area 145 is formed at the center of the bottom surface of the lens 140 corresponding to the recess 143. The reflective layer 144 reflecting the light inside is formed at portions except the recess 143 and the light passing region 145. As shown in FIG. 9, the concave portion 143 serves as a concave lens injecting the remaining portion to the bottom surface of the lens 140 except for partial light of the paraxial axis of the incident light 200. The upper surface 142 of the lens 140 forms a predetermined concave mirror to focus the light reflected from the reflective layer 144 on the bottom side of the lens 140 to be reflected back to the light passing area 145. Has the curvature of.

On the other hand, in the slider 130 positioned below the lens 140, a light transmission area or through hole 132 coaxial with an optical axis of the lens 140, that is, the light passing area of the lens 140 is formed. It is. The bottom surface of the slider 130 is formed with a bearing surface 131 for forming an air bearing on the median surface. The bearing surface 131 is located at both sides along the median rotation direction with respect to the through hole 132, and the bearing surface 131 opposite to the median rotation direction is formed in a 'c' shape. The bearing surface 131 located on the opposite side is 'I' type. Such a slider is made of a material such as Al ₂ O ₃ -TiC.

11 shows another example of the slider. Referring to FIG. 11, the bearing surface 131a is formed on the opposite side of the median rotation direction among the bottom surfaces of the slider 130a, which is a 'V' type in which the middle portion is cut off.

The slider as described above has a structure that prevents foreign matter from accumulating on the bearing surfaces 131 and 131a while achieving high stable flotation force by the bearing surfaces 131 and 131a properly disposed. The flotation force is strongly generated by the bearing surfaces 131 and 131a provided to face the rotational direction of the media, and the foreign matter accumulated on the bottom of the slider 130 including the bearing surfaces 131 and 131a is the direction in which the media rotates. It is effectively discharged through the open portion in the direction orthogonal to. On the other hand, the open portion of the V-shaped bearing surface 131a of the slider shown in FIG. 11 has a function of appropriately adjusting the passage of air to adjust the flotation force and a function of the passage of the foreign matter. Compared with the bearing surfaces 131 and 131a of such a structure, the charge area is greatly reduced, but a strong floating force due to its structural characteristics can be generated.

In the embodiment of the structure described above, the lens may be replaced by a plurality of lenses as in the conventional structure, it may have a structure as in the bearing surface or the conventional structure. In the floating optical head assembly of the present invention, first, the lens and the slider are provided at the top and bottom, and in some cases, the lens is provided on the elastic piece and the slider is provided at the bottom thereof. It is possible.

According to the present invention as described above, it is possible to simplify the structure of the head, in particular, when the lens and the slider in contact, assembling process by combining the lens and the slider first in the state of one assembly before engaging the elastic piece. Can be simplified. In addition, since the portion in which the floating force is generated and the head portion including the lens is provided on the coaxial, it is easy to adjust the floating force and also stably maintain the floating state. In particular, the mass of the slider can be reduced and downsized, so that operation is possible under a small lift force, and since the lens is in contact with the media through the slide, the collision or contact between the media and the head is particularly prevented.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be defined only in the appended claims.

Claims (17)

Suspension; A resilient piece that is fixed to the suspension in a cantilever form and is supported with a predetermined elasticity with respect to the suspension; It is fixed to the front end of the resilient piece is provided with a light transmission groove concave with a predetermined curvature in the central portion of one side, the light transmission region corresponding to the light transmission groove is provided on the other side, the light transmission groove and light Surfaces other than the transmission region include a lens having a reflective layer formed thereon; A slider which is located at the bottom of the lens and whose bearing surface is provided at the bottom of the lens; Floating optical head assembly, characterized in that provided. The floating optical head assembly of claim 1, wherein one side of the lens on which the recess is formed is a hemispherical shape having a predetermined curvature, and the other side of the lens is formed in a substantially planar shape. The through-hole having a predetermined diameter coaxial with the optical axis of the lens is formed in the distal end of the resilient piece on which the lens is mounted, and the through-hole provided in the distal end of the resilient piece is formed around the lens. Floating optical head assembly, characterized in that the flange is formed in contact with the circumference. The floating optical head according to claim 4, wherein a bottom of the slider is provided with a bearing surface located opposite to the rotational direction of the media, and in particular, the bearing surface is formed in a V shape with a center portion open. assembly. 4. The bearing surface of claim 1 or 3, wherein the bottom of the slider is provided with a bearing surface located opposite to the rotational direction of the media, and in particular, the bearing surface is formed in a V shape with a center portion open. Floating optical head assembly. 4. Floating optical head assembly according to claim 1 or 3, wherein the lens and the slider are in contact with one. 6. The floating optical head assembly of claim 5, wherein the lens and the slider are in contact with each other. The floating optical head assembly of claim 6, wherein the lens and the slider are in contact with each other. A light transmission groove concave to a predetermined curvature is provided in a central portion of one side thereof, and a light transmission region corresponding to the light transmission groove is provided on the other side thereof, and the reflective layer has a surface except for the light transmission groove and the light transmission region. A lens formed; A suspension having a protruding portion provided at one side of the distal end portion thereof; An elastic piece having one end fixed to the suspension in the form of a cantilever, contacting with a predetermined elasticity with respect to the protrusion of the suspension, and an end of which is provided with a through hole for mounting the lens; A slider which is located at the bottom of the lens and has a bearing surface for the media at its bottom and a coaxial light transmission area for the lens; Floating optical head assembly, characterized in that provided. The floating optical head assembly of claim 10, wherein one side of the lens in which the light transmitting groove is formed is a hemispherical shape having a predetermined curvature, and the other side of the lens is formed in a substantially planar shape. The through-hole having a predetermined diameter coaxial with the optical axis of the lens is formed at the tip of the resilient piece on which the lens is mounted, and the through-hole provided at the distal end of the resilient piece is disposed around the lens. Floating optical head assembly, characterized in that the flange is formed in contact with the circumference. 15. The floating optical head according to claim 13, wherein the bottom of the slider is provided with a bearing surface located opposite to the rotational direction of the media, and in particular, the bearing surface is formed in a V shape with a center portion open. assembly. 13. The bearing surface of claim 10 or 12, wherein the bottom of the slider is provided with bearing surfaces located opposite to the rotational direction of the media. In particular, the bearing surface is formed in a V-shape with a center portion open. Floating optical head assembly. 13. Floating optical head assembly according to claim 10 or 12, wherein the lens and the slider are in contact with each other. 15. The floating optical head assembly of claim 14, wherein the lens and the slider are in contact with one. 16. The floating optical head assembly of claim 15, wherein the lens and the slider are in contact with one. 11. The floating optical head assembly of claim 10, wherein the protrusion of the suspension is positioned adjacent to the lens.