JP2010056262A - Connecting structure of printed wiring boards and printed wiring board used for the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a connecting structure of printed wiring boards ensuring the connection of a plurality of printed wiring boards having many connection wirings and connection pad parts in a small connection space. <P>SOLUTION: A connecting structure of printed wiring boards connects first connection pad parts 19a and 19b of connection wirings 21a and 21b formed on the surface of a first printed wiring board 15 and a second connection pad part 31 of the connection wiring 12 formed on the surface of a second printed wiring board 11. The first printed wiring board is provided with a rectangular opening part 18 provided in the vicinity of an outer edge part 27, a first connection pad part arrayed and formed along an opening edge part 20b of the rectangular opening part, and a bypass connection wiring 21b going around the opening frame part 19 between the outer edge part 27 of the first printed wiring board and the rectangular opening part 18 and formed in such a manner as to be connected with a part of the first connection pad part. The first connection pad part and the second connection pad part are connected by being oppositely contacted at the edge part of the rectangular opening part. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a printed wiring board connection structure and a printed wiring board used therefor. More specifically, the present invention relates to a printed wiring board connection structure for connecting a plurality of printed wiring boards having a large number of connection wirings to each other.

  A plurality of printed wiring boards on which a large number of connection wirings are formed may be assembled while connecting the connection wirings. In recent years, with the miniaturization of electrical equipment, the wiring density of printed wiring boards has increased, and many wirings are often formed in a small space.

  For example, a hard disk drive includes a magnetic disk on which information is recorded and held rotatably by a motor, and a head stack assembly that holds a head core for reading and writing information on the magnetic disk so as to be swingable on the surface of the magnetic disk And is configured.

  The head stack assembly includes a carriage held swingably about an axis by a voice coil motor (VCM), and a suspension provided on an arm portion of the carriage, and a magnetic head portion provided at a tip portion of the suspension. The above-mentioned head core is held.

  The head core is connected to a circuit formed on a printed wiring board for suspension provided along the suspension, and information is read and written through this circuit. The suspension printed wiring board extends at the central portion of the suspension toward the swing center of the arm, and is drawn out to the carriage side portion at an intermediate portion of the arm portion. The base end portion of the suspension printed wiring board is connected to the main printed wiring board fixed to the side portion of the carriage.

  Conventionally, 4 to 6 signal circuits are drawn from each head core, and a corresponding number of connection wires are formed on the suspension wires. A connection pad portion formed by exposing a conductor to a predetermined range is formed at each end of the connection wiring of the printed wiring board for suspension, and is connected to the connection pad portion on the main printed wiring board side. Connected by soldering or the like.

Japanese Patent No. 4060810

  In the hard disk device as described above, a plurality of magnetic disks are rotatably arranged through a small gap, and the suspension printed wiring board is disposed in the gap between the magnetic disks. Therefore, the plurality of suspension printed wiring boards are connected to the main printed wiring board at the same interval as the disc interval. In the printed wiring board connection structure as described above, a large number of comb-like connection wirings are formed in the vicinity of the edge of the main printed wiring board.

  However, since the wiring space near the edge of the main printed wiring board is limited, the wiring pitch of the connection wiring is very small. Therefore, very high dimensional accuracy is required for the connection wiring formed on the printed wiring board. In addition, high assembly accuracy is required to connect the connection wirings of the two printed wiring boards, which may increase the defective rate of the product.

  Further, in the hard disk device corresponding to high density, the number of wirings drawn from the head core is increasing. However, as described above, the conventional connection structure cannot increase the number of wires any more. In order to avoid the inconvenience, a double-sided printed wiring board having connection wirings on both sides of the printed wiring board may be used. However, in order to manufacture a double-sided printed wiring board, since many processes are required, the problem that manufacturing cost increases arises.

  The present invention has been devised to solve the above-described problems, and provides a printed wiring board connection structure capable of reliably connecting a plurality of printed wiring boards having a large number of connection wirings in a small connection space. This is the issue.

  According to the first aspect of the present invention, the first connection pad portion of the plurality of connection wirings formed on the surface of the first printed wiring board and the plurality of connection wirings formed on the surface of the second printed wiring board. A connection structure of a printed wiring board for connecting a second connection pad portion, wherein the first printed wiring board is formed along a rectangular opening provided in the vicinity of an outer edge and an opening edge of the rectangular opening. The first connection pad portions arranged in a row and the opening frame portion between the outer edge portion and the rectangular opening portion are formed so as to be connected to a part of the first connection pad portions. And the first connection pad portion and the second connection pad portion are brought into contact with each other at the opening edge portion and connected.

  The form, arrangement position, and number of the rectangular openings are not particularly limited. It can be set according to the number of second printed wiring boards and the number of connection pads of each second printed wiring board. Further, the outer edge portion provided with the rectangular opening in the vicinity thereof can also be selected depending on the form of the connection wiring. Further, the rectangular openings can be provided in the vicinity of two or more outer edges.

  In the present invention, the bypass connection wiring formed so as to go around the opening frame portion between the outer edge portion of the first printed wiring board and the rectangular opening portion and connect to a part of the first connection pad portion. Is provided. By providing the detour connection wiring, the number of connection wirings on each printed wiring board can be increased without increasing the wiring pitch density of the connection wiring or increasing the assembly interval of the second printed wiring boards. It becomes possible. Further, since the wiring density of the first printed wiring board can be reduced, a reliable connection structure can be formed, and the reliability of the product is improved. Furthermore, since it is possible to increase the number of connection wirings that can be connected without substantially increasing the size of the printed wiring board, it is also possible to reduce the size of the electrical equipment employed.

  Further, by adopting the above configuration, it is possible to increase the number of connection wirings of each printed wiring board without adopting a double-sided printed wiring board, and it is possible to suppress an increase in manufacturing cost.

  The width dimension of the opening frame is not particularly limited, and may be set according to the number of connection wirings provided. For example, the minimum width that can form a required wiring can be set. Further, the form of the rectangular opening is not limited.

  For example, as in the invention described in claim 2, a plurality of the rectangular openings are provided along the outer edge, and each of the rectangular openings is formed in a direction orthogonal to the outer edge, and the first 1st connection pad part provided with the opening edge part in which 1 connection pad part was provided, and the said 2nd connection pad part of the said some 2nd printed wiring board was formed in each said opening edge part Can be connected to each other.

  In the case where a plurality of the second printed wiring boards are arranged and connected to the edge of the first printed wiring board, and the arrangement interval of the second printed wiring boards is small, the above-mentioned in the first printed wiring board The area between the rectangular openings is also reduced. For this reason, the number of wirings that can be arranged between the rectangular openings is limited. By adopting the above configuration, a part of the wiring extending from the connection pad can be bypassed, so that the number of connection pads and the connection wiring in the region can be increased. It is also possible to connect a plurality of second printed wiring boards having a large number of connection wirings to the first printed wiring board with a minimum pitch.

  Further, it is also possible to provide connection pad portions at the opening edge portions facing each other of the rectangular openings, and to connect two second printed wiring boards in one rectangular opening.

  As long as the first connection pad portion and the second connection pad portion can be brought into contact with each other and connected, the form of assembly of the first printed wiring board and the second printed wiring board is not limited. For example, the connection pad surfaces of both printed wiring boards can be brought into contact with each other and connected.

  According to a third aspect of the present invention, the second printed wiring board includes an extension portion that extends into the rectangular opening and has the second pad portion formed in an array, and the extension portion. Are extended into the opening so as to be orthogonal to the plate surface of the first printed wiring board, and the corresponding first connection pad portion and the second connection pad portion are respectively connected. Can be adopted.

  By adopting the above configuration, the extension portion and the rectangular opening can be used as a positioning portion when soldering or the like. Further, since the extending portion enters and is fixed to the rectangular opening, the mechanical assembly strength of both printed wiring boards is also improved.

  In the above connection structure, the printed wiring board is assembled such that the wiring surface is orthogonal to the opening edge of the rectangular opening. For this reason, in order to make the said 1st connection pad part and the said 2nd connection pad part contact | abut, it is preferable to provide the said 1st connection pad part extending to the edge of the said opening edge part.

  According to a fourth aspect of the present invention, the connection wiring of the first printed wiring board and the second printed wiring board is formed on one side of each printed wiring board.

  By employing the present invention, a large number of connection wirings and connection pads can be provided on one side of the printed wiring board. For this reason, even when the number of connection wirings increases, it is not necessary to employ a double-sided printed wiring board. Therefore, an increase in manufacturing cost can be suppressed.

  Note that at least the connection wiring and the connection pad for connecting the first printed wiring board and the second printed wiring board may be formed on one side of each printed wiring board, and the other circuit portions are printed on the printed wiring board. It can be formed on both sides.

  The type of printed wiring board to which the present invention is applied is not particularly limited. Rigid printed wiring boards can be connected to each other, and flexible printed wiring boards can be connected to each other.

  Further, as in the invention described in claim 5, the present invention can be applied to a connection structure in which at least one of the first printed wiring board and the second printed wiring board is a flexible printed wiring board.

  The invention described in claim 6 applies the present invention to a hard disk device. In this case, the second printed wiring board is applied to a suspension printed wiring board connected to a head for recording and reproducing information to and from a storage medium, while the first printed wiring board is used as a head stack. It can be applied to a main printed wiring board held on the side of the assembly.

  In the connection structure according to the present invention, when a plurality of printed wiring boards are connected, a large number of connection wirings can be connected in a small area. For this reason, it is suitable for the connection wiring of the head stack assembly in the hard disk device corresponding to high density. Further, it is not necessary to bend the end portion of the printed wiring board for suspension of the hard disk device along the plate surface of the main printed wiring board, and the manufacturing process can be reduced.

The invention described in claim 7 is an invention according to the first printed wiring board described above,
A printed wiring board comprising a plurality of connection wirings and pad portions formed at the ends of the connection wirings, wherein the pad parts are connected to pad parts provided in a plurality of connection wirings of another printed wiring board. A rectangular opening provided in the vicinity of the outer edge, the pad formed in an array along the opening edge of the rectangular opening, and an opening frame between the outer edge and the rectangular opening. A bypass connection wiring formed so as to wrap around and connect to a part of the pad part is provided, and the pad part and the pad part of the other printed wiring board are connected to each other.

The invention described in claim 8 is an invention according to the second printed wiring board described above,
Provided with a plurality of connection wirings and pad portions formed at the ends of these connection wirings, the pad portions connected to the pad portions provided at the opening edge portions of the rectangular openings formed in other printed wiring boards The printed wiring board is provided with an extending portion provided with the pad portion that extends into the rectangular opening portion and can be brought into contact with the pad portion provided at the opening edge portion. . As in the invention described in claim 9, a flexible printed wiring board can be adopted as the printed wiring board according to claim 7 or claim 8.

  The connection wiring connected to the connection pad provided at the edge of the rectangular opening wraps around the opening frame between the outer edge of the first flexible wiring board and the rectangular opening, and a part of the connection pad By providing the detour connection wiring connected to, the number of circuits can be increased without increasing the wiring density of the connection wiring, and a reliable connection structure can be obtained.

  Embodiments of the present invention will be specifically described below with reference to the drawings. In this embodiment, the present invention is applied to a printed wiring board connection structure in a hard disk device 1.

  FIG. 1 is an overall plan view of a hard disk device 1 to which the present invention is applied. The hard disk device 1 swings a plurality of magnetic disks 3 in which information is recorded in a case 2 and held rotatably by a motor, and a head core for reading / writing information on the magnetic disk 3 on the surface of the magnetic disk. And a head stack assembly 4 that is movably held.

  As shown in FIGS. 2 and 3, the head stack assembly 4 includes a carriage 7 that is swingably held around a shaft 13 by a voice coil motor 6 provided at a base end portion, and an arm portion of the carriage 7. 8 and a magnetic head portion 10 provided at the tip of the suspension 9 holds the head core (not shown).

  The head core is connected to a connection wiring 12 formed on a suspension printed wiring board 11 provided along the suspension 9, and information is exchanged via the connection wiring 12. The suspension printed wiring board 11 extends from the central portion of the suspension 9 toward the swing center 13 of the arm portion 8 and is pulled out to the side portion of the carriage 7 at the intermediate portion of the arm portion 8. The base end portion of the suspension printed wiring board 11 is connected to the main printed wiring board 15 fixed to the side portion of the carriage 7.

  As shown in FIG. 3, in the present embodiment, the three double-sided recording magnetic disks 3 are rotatably held through a predetermined gap H, and the suspension 9 is provided on both outer sides and the gaps H. . A sunpension printed wiring board provided with head portions 10 facing the magnetic disks on both sides is disposed on the suspensions on both outer sides. On the other hand, a pair of suspensions 9 are also inserted into the gap H in the intermediate portion, and a suspension printed wiring board is provided on these suspensions 9 provided with head portions 10 respectively facing the magnetic disk surfaces on both sides. Has been.

  FIG. 4 shows an enlarged plan view of the main printed wiring board 15. The main printed wiring board 15 according to this embodiment includes an amplification integrated circuit 16 for signal amplification at the center, and a connection portion 17 for connecting the suspension printed wiring board 11 to the suspension 9 side. Is formed.

  The connection portion 17 includes four rectangular openings 18, a plurality of connection pad portions 19 formed along the longitudinal opening edges 20 a and 20 b of the rectangular opening 18, and one end portion of the connection pad portions 19. Are provided with connection wirings 21a and 21b, respectively.

  As shown in FIG. 7, the main printed wiring board 15 includes an insulating layer 22 formed of a resin material, an adhesive layer 23 laminated on the insulating layer 22, and copper or the like on the adhesive layer 23. A conductor layer 24 formed by laminating conductor films and a covering insulating layer 26 joined so as to cover the conductor layer 24 via an adhesive layer 25 are configured. By forming the conductor layer 24 in a pattern, the connection wires 21a and 21b and the connection pad portion 19 are formed. Although not shown in FIGS. 4, 5, and 6, as shown in FIG. 7, the connection wiring except for the connection pad portions 19 has a coating insulating layer 26 through an adhesive layer 25. Is provided.

  In the present embodiment, the rectangular opening 18 is formed in the shape of a rectangular long hole, the longitudinal edges 20a and 20b are formed in a direction orthogonal to the outer edge 27 of the main printed wiring board 15, and the above Eight connecting pad portions 19 are formed at predetermined intervals along the longitudinal edges 20a and 20b. The connection pad portion 19 is formed up to the edge of the longitudinal edge portions 20a and 20b, and is exposed by removing the adhesive layer 25 and the insulating coating layer 26.

  The connection wiring according to the present embodiment includes an inner connection wiring 21a connected to the integrated circuit 16 through a region between the connection pad portion 19a and the rectangular opening 18, and a part of the connection pad portion 19b. To the opening frame 29 provided between the outer edge 27 of the main printed wiring board 15 and the inner edge 18a of the rectangular opening 18 and the vicinity of the lateral outer edge of the main printed wiring board 15. And the detour connection wiring 21b provided in FIG. In the present embodiment, the connection pad portions 19b and 19b from the inner edge portion 18a to the second are connected to the bypass connection wiring 21b. On the other hand, the other six pad portions 19a are connected to the integrated circuit 16 through the inner connection wiring 21a.

  By providing the bypass connection wiring 21b, the number of connection pads and the number of connection wirings can be increased without increasing the wiring density in the region between the rectangular openings. Therefore, it can be applied to a hard disk device or the like that employs a high-performance head core with many input / output wirings. In the main printed wiring board having the same number of connection wirings, the number of the inner connection wirings 21a can be reduced by the number of the bypass connection wirings. For this reason, the wiring density of the inner connection wiring 21a can be reduced to prevent a short circuit between the connection wirings.

  As shown in FIG. 5, each of the suspension printed wiring boards 11 includes eight connection wires 12 extending from the magnetic head portion 10 and eight connection pad portions formed at the ends of the connection wires 12. 31.

The connection pad portion 31 is formed in an extending portion 32 provided at the base end portion of the suspension printed wiring board 11. The extending portion 32 has a dimension corresponding to the length of the longitudinal edges 20a and 20b of the rectangular opening 18 of the main printed wiring board 15, and projects the width dimension of the suspension printed wiring board 11 to one side. It has a different form. In the longitudinal direction of the extending portion 32, the connection pad portions 31 are arranged at the same intervals as the connection pad portions 19 of the main printed wiring board. Each of the connection wires 12 is bent 90 degrees at the extension portion 32 and connected to the connection pad portion 31.

  As shown in FIG. 7, the printed wiring board for suspension 11 according to the present embodiment includes an insulating layer 33 formed of a resin material, an adhesive layer 34 formed on the insulating layer 33, and an adhesive. A flexible printed wiring board comprising: a conductor layer 35 formed by laminating a conductor film such as copper on the layer 34; and a covering insulating layer 37 joined so as to cover the conductor layer 35 via an adhesive layer 36 Is adopted. By forming the conductor layer 35 in a pattern, the connection wirings 12 and the connection pad portions 31 are formed. In the portion of the extension portion 32 where the connection pad portion 31 is formed, the insulating coating layer 37 is removed and the connection pad portion 31 is exposed. Although not shown in FIGS. 5 and 6, as shown in FIG. 7, also in the printed wiring board for suspension 11, the connection wiring other than the connection pad portion 31 is provided with an adhesive layer 36. A covering insulating layer 37 is provided so as to be covered.

  Next, a method for connecting the suspension printed wiring board 11 and the main printed wiring board 15 will be described with reference to FIGS.

  The suspension printed wiring board 11 extends to the arm portion 8 along the recording surface of the magnetic disk. On the other hand, the main printed wiring board 15 is fixed to the side surface of the carriage 7. Therefore, in the present embodiment, the suspension printed wiring board 11 and the main printed wiring board 15 are configured to be assembled with each other at an angle of 90 degrees.

  The longitudinal dimension of the extension 32 and the longitudinal dimension of the rectangular opening 18 are set to be the same. Therefore, as shown in FIG. 5, the suspension printed wiring board 11 and the main printed wiring board 15 are inclined at an angle of 90 degrees so that the extending portion 32 extends into the rectangular opening 18. it can. Moreover, the front and rear edge portions 32 a and 32 b of the extending portion 32 can be extended so as to be guided by the inner edge portions 18 a and 18 b of the rectangular opening portion 18. Therefore, it is possible to very easily position each connection pad portion 31 of the suspension printed wiring board 11 and the corresponding connection pad portion 19 of the main printed wiring board 15 corresponding thereto.

  The connection pad portion 19 of the main printed wiring board 15 is formed up to the opening edge portions 20a and 20b where these are formed, and the covering insulating layer 26 is removed. Further, the insulating coating layer 36 of the connection pad portion 31 of the suspension printed wiring board 11 is also removed. For this reason, as shown in FIG. 7, the connection pad portion 19 of the main printed wiring board 15 and the connection pad portion 31 of the suspension printed wiring board 11 can be brought into perpendicular contact with each other.

  While maintaining the above-mentioned posture, solder 38 is piled up between the connection pad portion 19 and the connection pad portion 31 so as to be joined, and as shown in FIGS. The printed wiring board 11 and the main printed wiring board 15 are assembled in a state where the pad portions 19 and 31 are electrically connected.

  In the present embodiment, by providing the bypass connection wiring 21b, it is possible to connect printed wiring boards provided with a large number of connection wirings and connection pads on one side via a small connection space. Further, the printed wiring board to be connected can be easily positioned. In addition, since the two printed wiring boards 11.15 can be assembled so that the extending portion 32 is fitted into the rectangular opening 18, the mechanical joint strength between these two printed wiring boards can be increased. .

  In the present embodiment, the example in which the rectangular opening 18 is provided in the vicinity of the one outer edge 27 has been described. However, the rectangular opening can be provided on the inner side of the printed wiring board. In this case, a part of the wiring provided in the region between the rectangular openings can be drawn out from one side of the region as a bypass connection wiring, and the other wiring can be drawn out from the other side. . Thereby, the number of wirings provided between the regions can be increased without reducing the pitch between the wirings, as in the above embodiment. Further, since the width of the opening frame portion is increased, a semiconductor chip or the like can be disposed on the opening frame portion.

  The present invention is not limited to the embodiment described above. It should be thought that embodiment disclosed this time is an illustration and restrictive at no points. The scope of the present invention is defined not by the above-described meaning but by the scope of the claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of the claims.

  By adopting the connection structure of the printed wiring board according to the present invention, it is possible to connect the printed wiring boards provided with a large number of connection wirings and connection pads to each other without using a double-sided printed wiring board provided with connection wirings on both sides. It becomes possible to connect via.

It is a top view which shows the internal structure of the hard disk to which the connection structure of the printed wiring board which concerns on this invention is applied. It is a top view of the head stack assembly of the hard disk shown in FIG. FIG. 3 is a right side view of the head stack assembly shown in FIG. 2. It is an enlarged plan view of a main printed wiring board (first printed wiring board). It is a partially expanded perspective view which shows the connection method of the main printed wiring board (1st printed wiring board) and the printed wiring board for suspensions (2nd printed wiring board). It is a partially expanded perspective view showing a connection structure of a main printed wiring board (first printed wiring board) and a suspension printed wiring board (second printed wiring board). It is a figure which shows the principal part cross section of the connection structure which concerns on this embodiment, and is a principal part expanded sectional view which follows the VII-VII line shown in FIG. It is a whole perspective view which shows the connection structure of the main printed wiring board (1st printed wiring board) and the printed wiring board for suspensions (2nd printed wiring board).

Explanation of symbols

15 Main printed wiring board (first printed wiring board)
19 Connection pad part of the main printed wiring board (first connection pad part)
20a Opening edge 20b Opening edge 21a Connection wiring 21b Detour connection wiring 11 Printed wiring board for suspension (second printed wiring board)
12 connection wiring 31 connection pad portion of suspension printed wiring board (second connection pad portion)
18 Rectangular opening 27 Outer edge 28 Inner edge 29 Opening frame

Claims (9)

The first connection pad portions of the plurality of connection wirings formed on the surface of the first printed wiring board are connected to the second connection pad portions of the plurality of connection wirings formed on the surface of the second printed wiring board. A printed wiring board connection structure,
The first printed wiring board is
A rectangular opening provided near the outer edge,
The first connection pad portion arranged along the opening edge of the rectangular opening;
A detour connection wiring formed to wrap around an opening frame between the outer edge and the rectangular opening and connect to a part of the first connection pad,
The printed wiring board connection structure, wherein the first connection pad portion and the second connection pad portion are connected to each other at the opening edge portion. A plurality of the rectangular openings are provided along the outer edge,
Each rectangular opening is formed in a direction orthogonal to the outer edge, and includes an opening edge provided with the first connection pad.
The said 2nd connection pad part of several said 2nd printed wiring boards is each connected to the said 1st connection pad part formed in each said opening edge part, It is comprised, respectively. Printed wiring board connection structure. The second printed wiring board includes an extending portion in which the second pad portions are arranged,
The extension part is extended into the opening so as to be orthogonal to the plate surface of the first printed wiring board, and the corresponding first connection pad part and the second connection pad part are The printed wiring board connection structure according to claim 1, wherein each is connected.   The printed wiring board connection structure according to any one of claims 1 to 3, wherein the connection wiring is formed on one surface of each printed wiring board.   The connection structure of the printed wiring board according to any one of claims 1 to 4, wherein at least one of the first printed wiring board and the second printed wiring board is a flexible printed wiring board. A hard disk device comprising the printed wiring board connection structure according to any one of claims 1 to 5,
The first printed wiring board is a main printed wiring board held on the side of the head stack assembly,
The hard disk device, wherein the second printed wiring board is a suspension printed wiring board connected to a head unit for recording and reproducing information on a storage medium. A printed wiring board comprising a plurality of connection wirings and pad portions formed at the ends of the connection wirings, wherein the pad parts are connected to pad parts provided in a plurality of connection wirings of another printed wiring board. There,
A rectangular opening provided near the outer edge,
The pad portion arranged along the opening edge of the rectangular opening;
A detour connection wiring formed to wrap around an opening frame between the outer edge and the rectangular opening and connect to a part of the pad,
The printed wiring board comprised so that the said pad part and the pad part of said other printed wiring board might be connected. Provided with a plurality of connection wirings and pad portions formed at the ends of these connection wirings, the pad portions connected to the pad portions provided at the opening edge portions of the rectangular openings formed in other printed wiring boards Printed wiring board,
A printed wiring board comprising: an extension portion provided with the pad portion that extends into the rectangular opening portion and can come into contact with the pad portion provided at the opening edge portion.   The printed wiring board according to claim 7, wherein the printed wiring board is a flexible printed wiring board.

Images