KR0164029B1 - Magnetic disk apparatus having a relay flat cable - Google Patents

Abstract

A relay flexible cable for relay connection of a magnetic disk device, comprising: electrically connecting at least one arm to the disk device in a direction parallel to the disk for supporting a magnetic head for writing and reading information to or from the magnetic disk device; A first flat cable having one end connected to the rotary actuator for connection, and a second flat cable installed on the side of the arm for electrically relaying the magnetic head to the first flat cable. A flat cable comprising a plurality of rods arranged in the extending direction of the arm, the second flat cable being provided at one end of the second flat cable for electrical connection to the magnetic head and extending in the arm A first land group having a plurality of lands disposed along the ground, for electrical connection to the first flat cable And a second land group having a plurality of lands provided at the other end of the second flat cable and arranged along the extending direction of the arm and disposed in a face-to-face relationship with the lands of the first flat cable. It is done.

Description

Magnetic disk device having a relay flexible cable for relay connection.

1 is a schematic diagram of a relay FPC for the actuator of FIG. 1b.

2 is a block diagram of another embodiment of the relay FPC of FIG.

3a is a left half view of an FPC substrate for the relay FPC of FIG.

3b is a right half side view of the FPC substrate for the relay FPC of FIG.

4 is an enlarged view of the main FPC end for the relay FPC of FIG.

5a and 5b are FPC substrate attachment process diagrams (first process diagram).

6A and 6B are FPC board attachment process diagrams (second process diagram).

7 and 7b are FPC board attachment process diagrams (third process diagram).

8A and 8B are FPC board attachment process diagrams (Fourth process diagrams).

The present invention relates to a magnetic disk device, and more particularly, to a magnetic disk device having a relay flexible printed cable (FPC) for relay connection.

In the conventional configuration, the lead wire from the magnetic head 30 extends to the side of the arm 33 and is led to the main FPC 40 provided near the end of the arm 33.

Then, the lead wire is bonded to the land groups 400 and 401 of the main FPC 40. After bonding, the lead wire is fixed to the side of the arm 33 by adhesion or the like.

In such a conventional configuration, in order to draw the lead wire from the magnetic head 30 to the lad groups 400 and 401 of the main FPC 40, the lead wire becomes long. For this reason, unbonded lead wires are disturbed during bonding of the lead wires, resulting in deterioration of workability. In addition, when the lead wires are collectively bonded to the arm 33, careful work is required to prevent the fine lead wires from being cut.

Furthermore, since the lead wires for two magnetic heads are collectively fixed to the arm 33, one of the magnetic heads may be damaged, and a great deal of time is consumed when removing the damaged head from the arm 33. Specifically, a means for removing lead wire bonding of two magnetic heads once, peeling off two lead wires from the arm 33, and removing a damaged magnetic head is required. After replacing the damaged magnetic head, it is necessary to reverse it. That is, twice the labor is required to replace one magnetic head.

This problem becomes more serious when using the MR head as the readhead. That is, in the case of the conventional inductive head, since there are two lines of lead wires, the number of lead wires in the MR head increases by four lines, that is, it becomes more difficult to handle the lead wires than before. In particular, when replacing the magnetic heads, in order to replace one magnetic head, it is necessary to remove the bonding of eight parts, strip off the wiring of eight lines of wires, and replace the magnetic heads. This makes the work efficiency even worse.

In addition, since the rib width of the arm 33 and the length of the arm 33 are long as described above, the work efficiency is further deteriorated.

Accordingly, an object of the present invention is to solve the conventional problems as described above.

According to one aspect of the present invention, an object of the present invention as described above is configured as follows;

At least one magnetic disk,

Rotating means for rotating the magnetic disk;

A magnetic head for writing and reading information to or from the magnetic disk;

A rotatable actuator having at least one arm extending in a direction parallel to the disk for supporting the magnetic head, and for moving the magnetic head;

A first flat cable having one end connected to the rotary actuator for electrical connection to the disk device;

And a second flat cable installed on the side of the arm to electrically relay the magnetic head to the first flat cable.

The first flat cable includes a plurality of lands disposed in an extension direction of the arm,

A first land group having a plurality of lands provided at one end of the second flat cable and arranged along an extension direction of the arm for electrical connection to the magnetic head of the second flat cable;

A plurality of ends provided at the other end of the second flat cable for electrical connection to the first flat cable, arranged along the extending direction of the arm, and arranged in a mutually facing relationship with the lands of the first flat cable; A magnetic disk apparatus having a relay flexible cable for relay connection characterized by having a second land group having lands.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a relay FPC of a magnetic disk device according to the present invention, FIG. 2 is a configuration diagram of another example of the relay FPC of the present invention, FIG. 3a is a left half view of a relay FPC substrate, and 3b is a relay FPC. Fig. 4 is an enlarged end view of the main FPC, and Figs. 5A to 8B are process diagrams for attaching a relay FPC using the relay FPC substrates shown in Figs. 3A and 3B.

In FIG. 1, a relay FPC (flexible print cable) 60 is provided on the side of the arm 33. The relay FPC 60 has a first land group 600 at a head side end of the tip, and a second land group 601 at a main FPC side end of the rear end. The first land group 600 and the second land group 601 are connected to each other via a lead pattern not described in the relay FPC 60.

The relay FPC 60 is fixed to the side of the arm 33 and the main FPC 60 by double-sided tape. The second land group 601 of the relay FPC 60 is located at the position of the land groups 400 and 401 of the main FPC 40.

The lead wire 300 from the magnetic head 30 is bonded to the first land group 600 of the relay FPC 60. On the other hand, the land groups 400 and 401 of the main FPC 40 are connected to the second land group 601 of the relay FPC 60 by bonding or soldering. Therefore, the magnetic head 30 is electrically connected to the main FPC 40 via the lead wire 300 and the relay FPC 60.

The reason why the relay FPC 60 is installed in this way is explained.

In this embodiment, instead of extending the lead wire to the side of the arm 33, the relay FPC 60 is provided. For this reason, handling of wiring material is easy in a bonding job. In addition, the bonding operation can be improved because there is no need to be careful about the cutting of the lead wires. In addition, the yield associated with cutting the lead wire is also improved. Furthermore, in the head replacement work, only the bonding between the relay FPC 60 and the lead wire 300 is removed, so that the head replacement work can be made more efficient.

2 is another embodiment of a relay FPC. The width of the relay FPC must be less than or equal to the width of the arm 33. However, when the relay FPC is applied to the MR head, eight lead patterns are required for the relay FPC. Therefore, if the width of the FPC is made within the width of the arm 33, the width of the lead pattern is very small. For example, an FPC having a pattern width of about 50 μm is required. FPC of such a fine pattern is expensive.

On the other hand, in the embodiment of Fig. 2, two relay FPCs 60-1 and 60-2, each of which has four patterns, are overlapped. That is, the second relay FPC having the first land group 602 and the second land group 603 in the first relay FPC 60-1 having the first land group 600 and the second land group 601. (60-2) is laminated.

In this case, since the pattern width of each relay FPC 60-1, 60-2 needs only about 100 micrometers, cheap FPC can be used. This relay FPC is cheaper because it has a pattern of one layer. In addition, the pattern width can be increased even when using a multilayer FPC. However, this FPC is more expensive than the one-layer FPC.

In this way, when the MR head is used, even when there are many connecting players, it is possible to connect using a low-cost FPC.

Next, the process of attaching the relay FPC described above to the actuator 32 will be described. The ladder relay FPC substrate 61 shown in Figs. 3A and 3B is used. 3A is a right half view of the ladder type FPC board 61, and FIG. 3B is a left half view of the ladder type FPC board 61. FIG.

The substrate 61 has a base 61-2 on which a plurality of windows 610 and a second land group 601 are formed at the left end of the substrate 61 as shown in 3a. Then, bars 61-1 corresponding to each arm 33 are provided on the base 61-2 as many as the number of arms 33. Furthermore, as shown in FIG. 3B, each bar 61-1 is connected to the right end of the substrate 61 by the connecting portion 61-3.

That is, this board | substrate 61 is equipped with several relay FPC in parallel, and has a ladder shape which perforated the part between arms 33. FIG.

In addition, as shown in FIG. 4, the land group 400 is branched at the end of the main FPC 40. This land group 400 is composed of four lands corresponding to one magnetic head 30. By arranging the land groups 400 in the above manner in this manner, the land groups 400 respectively connected to the lead patterns can be accommodated in the main FPC 40 having a width within the height of the actuator 32. For this reason, the width of the main FPC 40 can be made into the height of the actuator 32. FIG.

Next, the attaching process of the FPC substrate will be described with reference to the fifth to eighth.

First, as shown in 5a, the main FPC 40 is fixed to the root of the arm 33 of the actuator 32. 5B is an enlarged view of portion A of the fifth portion, and the main FPC 40 has a large number of land groups 400.

Next, as shown in 6a, the above-described FPC substrate 61 is attached to the main FPC 40 and the arm 33 of the root of the arm 33. At this time, the land group 400 of the lower main FPC 40 is exposed from the window 610 of the FPC board 61 as shown in 6b which is an enlarged view of the portion B of 6a. The second land group 601 of the FPC substrate 61 is in a position facing the land group 400.

Next, as shown in 6a, the connection portion 61-3 of the FPC substrate 61 is cut. Then, as shown in FIG. 7B, which is an enlarged view of part C of FIG. 7A, the land group 400 of the main FPC 40 exposed from the window 610 of the FPC substrate 61 and the second of the FPC substrate 61 are exposed. The land group 601 is bonded by the bonding line 62.

As shown in FIG. 8A, a suspension 34 to which the magnetic head 30 is attached is attached to the tip of the arm 33. As shown in FIG. As shown in FIG. 8B, which is an enlarged view of part D of FIG. 8A, the lead wire 300 of the magnetic head 30 is bonded to the first land group 600 of each bar 61-1 of the FPC substrate 61. do.

This can facilitate the attachment work by handling the relatively large FPC substrate 61. Therefore, even if the arm width is about 2mm, the relay FPC 60 can be easily attached.

Although the present invention has been described above by way of examples, various modifications are possible within the scope of the gist of the present invention, and this is not excluded from the scope of the present invention.

As described above, according to the present invention, the bonding work can be improved since the handling of the wiring material is easy in the bonding work and the need for careful cutting of the lead wire is not required. In addition, the yield associated with cutting the lead wire is also improved, and furthermore, the head replacement work can be made more efficient since only the bonding between the relay FPC 60 and the lead wire 300 is removed at the time of head replacement work. can do.

Claims (2)

At least one magnetic disk, rotating means for rotating the magnetic disk, a magnetic head for writing and reading information to and from the magnetic disk, and extending in a direction parallel to the disk for supporting the magnetic head A first flat cable having at least one arm and having a rotatable actuator for moving the magnetic head, one end connected to the rotatable actuator for electrical connection to the disk device, And a second flat cable installed on the side of the arm for electrically relaying the magnetic head, wherein the first flat cable includes a plurality of lands disposed in an extension direction of the arm, and the second flat cable One end of the second flat cable for electrical connection to the magnetic head and A first land group having a plurality of lands arranged along an extending direction of the arm and provided at the other end of the second flat cable for electrical connection to the first flat cable and arranged along the extending direction of the arm And a second land group having a plurality of lands arranged in a mutually facing relationship with the lands of the first flat cable. The magnetic disk apparatus according to claim 1, wherein the width of the second flat cable is equal to or smaller than the width of the side surface of the arm.