KR940002976Y1 - Bearing regulation apparatus for hi-density fdd - Google Patents

Abstract

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Description

Azimuth adjustment of high density floppy disk drive

1 is a main sectional view showing a conventional high density floppy disk drive.

Figure 2 is a main cross-sectional view for explaining the azimuth adjusting device of the present invention.

Figure 3a, b is a main portion operation state diagram for explaining the angle adjustment state of the guide bar of the present invention device.

* Explanation of symbols for main parts of the drawings

1 Base 2 Stepped portion

3: head 4: guide protrusion

5: guide bar 6: leaf spring

7 step motor 8 shaft

8 ': threaded portion 9: support

10: pin 11: tab hole

12: screw 12 ': tapered portion

The present invention relates to an azimuth adjusting device of a floppy disk drive for high density, and particularly, a tapered screw with an end of the guide bar at which the head is slid forward and backward. It relates to an azimuth control device of a high density floppy disk drive that can be easily adjusted using.

In the conventional high density floppy disk drive, as shown in FIG. 1, the head 33 is moved to the guide bar support surface 32 formed on the inner surface of one side of the floppy disk drive (hereinafter abbreviated as FDD) base 31. Both ends of the guide bar 35 on which the guide protrusion 34 of one side is slidably mounted on the base bar 35 are pressed by the plate spring 36 screwed to the base 31 so as to be slidable in the rear direction, and the base 31 The shaft 38 of the step motor 37 fixed to the outside is fixed to the inner surface of the device so that its end is rotatably assembled to the support 39 fixed to the bottom surface of the base 31. 38 has a structure in which a threaded portion 38 'is formed to engage the free end of the pin 40 protruding from the shaft-side central portion of the head 33.

Therefore, when the step motor 37 rotates forward, the pin 40 coupled to the threaded portion 38 ′ of the shaft 38 of the step motor 37 moves in the direction A in FIG. 1. When the step motor 37 reversely rotates, the head 33 moves forward (in the B direction) so that the data stored in the desired position can be read or recorded.

However, such a configuration requires that the guide bar support surface formed on the inner surface of the base be processed very precisely and accurately. However, if a slight processing error occurs, the azimuth angle of the assembled head is incorrect and the data stored in the floppy disk can be read. Not only does a data error occur at the same time, but once the mass-produced base is impossible to modify, the machining of the base is very difficult, and the work and assembly processes are very complicated and sensitive, resulting in increased production cost. Since both ends of the guide bar are fixed to the guide bar support surface, there is a problem that cannot be corrected once the azimuth angle of the head is twisted.

Therefore, in the present invention, the tap hole leading to one corner of the guide bar support surface on which the both ends of the guide bar on which the head is fixed is processed on the base, and the tapered screw is coupled to the base by machining and assembly errors. If the azimuth angle is different from the standard angle, the other components do not need to be disassembled. Only tighten or loosen the screw from the outside of the base so that the azimuth angle of the guide bar can be changed. It can be adjusted to, the purpose is described in detail with reference to the accompanying drawings as follows.

As shown in FIGS. 2 and 3a, the azimuth adjusting device of the present invention assembles the head 3 so as to be slidable forward and backward on the guide bar support surface 2 formed inside the FDD base 1. Both end portions of a guide bar 5 are mounted on the base 1 and fixed by screw plate 6 fixed with screws, and fixed to the outside of the base 1 to protrude into the device. The shaft 8 is rotatably installed on the support 9 fixed to the bottom surface of the base 1, but the shaft 8 is formed with a screw portion 8 'so that the shaft 3 of the head 3 has a central portion. In the FDD formed by joining the free ends of the protruding pins 10, the base 1 is machined with a stepped hole 11 leading to the edge of one side guide bar support surface 2, and the stepped hole 11 is formed. The tapered portion 12 'of the screw 12 is guided by coupling the tapered screw 12 in a conical shape. Is a hayeoseo to abut on the outer peripheral surface of one end (5).

In addition, even when the tapered portion 12 'is formed in an R-shape (round) or a groove opposing the outer circumferential surface of the guide bar 5, the same effect can be obtained in adjusting the azimuth angle of the head 3. .

Here, reference numeral 4 denotes a guide protrusion, and θ ₁ and θ ₂ indicate an amount of change in the azimuth angle of the head 3, which may be changed by the front and rear adjustment amount of the screw 12.

Referring to Figures 2 and 3a, b the effect of the present invention configured as described above is as follows.

First, the guide bar 5 and the threaded portion 8 'assembled at both support holes of the guide protrusion 4 of the head 3 are integrated in the FDD base 1 on which the guide bar supporting surface 2, which has been precisely processed, is integrated. The step motor 7 formed in the structure is fixed, and the screw 12 is properly tightened by tightening the screw 12 to the stepped hole 11 processed to the edge of the guide bar support surface 2, and then the power source to the step motor 7. When the voltage is applied, the step motor 7 is rotated in the forward or reverse direction controlled by a microcomputer (not shown), so the pin 10 screwed to the threaded portion 8 'of the shaft 8 of the step motor 7 is mounted. ) Moves in the direction A or B of FIG. 2 so that the head 3 coupled thereto slides forward and backward along the guide bar 5 to read data contained in a floppy disk or to store predetermined data. It becomes possible.

At this time, when the screw 12 is coupled to the tab hole 11 of the base 1 and its conical tapered portion 12 ′ contacts the outer peripheral surface of one side of the guide bar 5, the screw 12 rotates left and right. Since the guide bar 5 is rotated to the left and right by a predetermined angle around the other leaf spring 6, the head 3 coupled to the guide protrusion 4 has a maximum predetermined angle θ from the central axis. ₁ , θ ₂ ) to be rotated by the user can easily adjust the azimuth of the head 3 to the desired angle.

That is, after assembling the hag 3 and the like into the base 1, the azimuth angle of the head 3 is tested, and as a result, the head 3 is centered on a reference line. ₁ ) the azimuth angle of the head 3 is a predetermined angle with respect to the reference line. ₂ ) If the gap is opened to the outside by tightening the screw 12 coupled to the screw hole 11 by a predetermined amount, the guide bar 5 is centered on the other leaf spring 6 by a predetermined angle, respectively. Since it rotates to the left and right, the head 3 coupled to the guide protrusion 4 is rotated by a predetermined angle (θ ₁ , θ ₂ ), respectively, so that the azimuth angle of the head 3 can be adjusted to a desired angle.

In this case, the leaf spring 6 generates a predetermined elastic force to prevent the guide bar 5 from being separated from the guide bar support surface 2.

In addition, the conical tapered portion 12 ′ formed on the screw 12 abuts against an outer circumferential surface of one end portion of the guide bar 5 to allow the guide bar 5 to move smoothly, as well as the guide part. By allowing (5) to be moved in a micro-quantity, it plays a role of adjusting the azimuth angle of the head 3 to a fine angle.

As described above, according to the device of the present invention, an elastic force for moving the guide portion 5 to the corner portion of the guide bar support surface 2 when the azimuth angle of the head generated in the processing process of the base and the assembly process of the head, etc. Will be generated.

In addition, the conical tapered portion 12 ′ formed on the screw 12 abuts against an outer circumferential surface of one side end portion of the guide bar 5 so that the guide portion 5 can be moved in a minute amount to azimuth angle of the head 3. It serves to control the fine angle.

As described above, according to the device of the present invention, the azimuth error of the head generated during the processing of the base and the assembling process of the head is coupled to the screw hole from the outside of the base without having to disassemble the respective components constituting the FDD. The screw can be easily adjusted by simply tightening or releasing the screw, so that the assembly and productivity can be improved, and the reliability of the product can be further improved.

Claims (3)

Both ends of the guide bar 5 with the head 3 coupled to the guide bar support surface 2 formed on one side inner surface of the FDD base 1 are pressed and fixed with a plate spring 6 screwed to the base 1. The shaft 8 end of the step motor 7 fixed to the bottom outer surface of the base 1 and protruding into the device is rotatably coupled to the support 9 fixed to the bottom surface of the base 1. However, in the FDD formed by engaging the free end of the pin 10 protruding from the other middle of the head 3 by machining the threaded portion 8 'to the shaft 8, the outer surface of the base 1 And a stepped hole 11 penetrating between the corners of the guide bar support surface 2 and the screw hole 12 coupled to the stepped hole 11 so that the tip of the screw 12 is guided. Predetermined angle by the degree of entry of the azimuth screw of the guide bar 5 to abut the outer surface of one side end of the bar 5 High density azimuth adjustment of the floppy disk drive, characterized in that to go from the stomach. 4. The apparatus of claim 3, wherein the tapered portion (12 ') of the screw (12) is rounded at the top. The azimuth adjusting device of the high density floppy disk drive according to claim 2, wherein the tip of the screw (12) is a flat surface and the tip of the guide bar (5) facing the screw is formed in a concave shape.