JP2005071539A - Wiring board, its manufacturing method, head mechanism, and magnetic disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a magnetic disk device which can perform high speed transfer and is excellent in maintainability. <P>SOLUTION: This relay FPC 26 has writing lines 26a, 26b for transmitting a writing signal, a reading line 26c wired separating from the writing lines 26a, 26b and transmitting a reading signal, and a reading line 26d wired at a different position separating from the writing lines 26a, 26b and transmitting a reading signal, such at least one point exists that distance between the writing lines 26a, 16b and the reading line 26c coincides with distance between the writing lines 26a, 16b and the reading line 26d. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a (magnetic) disk device, and more particularly to an FPC (Flexible Printed Circuit board) for transmitting a read signal and a write signal. The FPC of the present invention is, for example, a relay FPC that is arranged in a head arm and exchanges signals acquired by the head, and is suitable for a magnetic disk device having a large capacity and a high transfer speed.

  In recent years, with the widespread use of digital cameras and digital video cameras, it has become necessary to read and write large-capacity image and video information at high speed, and magnetic disk devices that record information have excellent maintainability and high-speed transfer. It is desired. A magnetic disk device generally reads and writes information on a magnetic disk by a head, and exchanges information acquired by the head with an IC chip via an FPC. An IC chip is an integrated circuit that processes a transmission signal from the head and a transmission signal to the head. The magnetic disk device includes a magnetic disk, a head arm, a head, and a relay FPC. The magnetic disk is a circular storage carrier that stores information from the head, and stores information in storage areas called sectors and tracks. The head arm is substantially fan-shaped when viewed from above, and is arranged so as to sandwich the magnetic disk. The tip of the head arm is connected to the head and rotates the head in the horizontal direction. The head reads and writes information on the magnetic disk, and is connected to the head arm via a suspension. The relay FPC is a wiring provided for transmitting information between the head and the IC chip. The relay FPC is arranged on the side surface of the head arm to make it less susceptible to airflow resistance, and a write unit that transmits a signal to be written to the magnetic disk, and a lead unit that transmits a signal read from the magnetic disk have. One end of these wirings is connected to the head and reads and writes information. Therefore, since electric wires (wiring) for inflow and outflow are necessary, the electric wires of the lead part and the write part are composed of a pair of electric wires, and a total of four lines are parallel to the head arm. Be placed. The write part and the lead part are conductive films, and the periphery thereof is covered with an insulating film, and the interference between the electric wires is prevented by the insulating film.

However, the write portion has a larger amount of current flowing in and out than the read portion. If the current amount in the read portion is about 2.4 to 3.4 mA, the amount of current flowing into and out of the write portion is about 25 to 60 mA. A current gap of 10 times or more is generated.
For this reason, a potential difference is generated between the read portion and the write portion of the relay FPC, causing current leakage (injection) from the write portion to the read portion. That is, of the two lead portions, the lead portion that is close to the write portion has more injection from the write portion than the far lead portion, and the life of the lead portion is reduced. As a result, a magnetic disk device with excellent maintainability could not be provided.

  Further, the FPC is operated by limiting the amount of current flowing through the read element to the extent that the influence of the injection from the write unit does not occur in order to extend the life of the magnetic hard disk. Therefore, sufficient head characteristics cannot be obtained, and the head design is difficult.

  Accordingly, it is a general object of the present invention to provide a new and useful magnetic disk device that solves such conventional problems.

  More specifically, an object of the present invention is to provide a magnetic disk device capable of high-speed transfer and excellent in maintainability.

  In order to achieve the above object, a wiring board according to an exemplary aspect of the present invention is configured to transmit a read signal, a first electric wire for transmitting a write signal, and a wiring separated from the first electric wire. A second electric wire, and a third electric wire that is separated from the first electric wire and is arranged at a position different from the second electric wire and transmits a read signal, and the first electric wire and the second electric wire It is characterized in that there is at least one point where the distance to the electric wire matches the distance between the first electric wire and the third electric wire.

  According to this wiring board, the second and third electric wires can divide the injection received from the first electric wires. Therefore, the second and third electric wires can reduce such injection. That is, the potential difference between the second and third wires can be reduced. As a result, the influence on the second and third electric wires is reduced, and the life of elements such as the magnetic head connected to the wiring board and the wiring board can be improved. Can be provided. Furthermore, the wiring board does not need to be restricted in sense current in consideration of injection, and can improve the characteristics of the head. Therefore, the wiring board can cope with high-speed transfer.

  When the second electric wire and the third electric wire are configured to intersect, the second electric wire is closer to the first electric wire than the third electric wire, and the third electric wire is third. This means that there is a portion closer to the second wire than the second wire. The injection received from the first electric wire depends on the distance from the first electric wire. Specifically, the injection occurs due to a potential difference based on a difference in distance from the first electric wire to each electric wire. By configuring in this way, for example, the potential of the second electric wire is higher in a portion closer to the second electric wire, and the potential of the third electric wire is higher in a portion closer to the third electric wire. The respective electric potentials cancel each other, and as a result, the injection to the second and third electric wires can be reduced. Therefore, it is possible to improve the life of elements such as a wiring board and a magnetic head connected to the wiring board, and thus it is possible to provide a wiring board with excellent maintainability. Further, the wiring board does not need to be restricted in sense current in consideration of injection, and can transfer a large amount of information. Therefore, the wiring board can cope with high-speed transfer.

  A head mechanism according to another aspect of the present invention includes the above-described wiring board.

  According to such a head mechanism, the second and third electric wires can divide the injection received from the first electric wire. Therefore, the second and third electric wires can reduce such injection. That is, the potential difference between the second and third wires can be reduced. When the second electric wire and the third electric wire are configured to cross each other, for example, the potential of the second electric wire is high in a portion where the second electric wire is closer, and the third electric wire is in a portion where the third electric wire is close. The potential of becomes higher. The respective electric potentials cancel each other, and as a result, the injection to the second and third electric wires can be reduced. As a result, the influence on the second and third electric wires is reduced, and it is possible to improve the life of the wiring board and the head connected to the wiring board, so that a wiring board with excellent maintainability is provided. Can do. Further, the wiring board does not need to be restricted in sense current in consideration of injection, and can transfer a large amount of information. Therefore, the wiring board can cope with high-speed transfer.

  A magnetic disk device according to another aspect of the present invention is characterized by having the above-described wiring board.

  According to such a magnetic disk device, the second and third electric wires can divide the injection received from the first electric wire. Therefore, the second and third electric wires can reduce such injection. That is, the potential difference between the second and third wires can be reduced. When the second electric wire and the third electric wire are configured to cross each other, for example, the potential of the second electric wire is high in a portion where the second electric wire is closer, and the third electric wire is in a portion where the third electric wire is close. The potential of becomes higher. The respective electric potentials cancel each other, and as a result, the injection to the second and third electric wires can be reduced. As a result, the influence on the second and third electric wires is reduced, and the life of the magnetic head connected to the wiring board and the wiring board can be improved. Thus, a wiring board having excellent maintainability is provided. be able to. Further, the wiring board does not need to be restricted in sense current in consideration of injection, and can transfer a large amount of information. Therefore, the wiring board can cope with high-speed transfer.

  A wiring board manufacturing method according to another aspect of the present invention is a wiring board manufacturing method for transmitting a write signal and a read signal, and includes a second electric wire and a third electric wire for transmitting the read signal. A step of crossing the second electric wire and the third electric wire, and a step of covering the second electric wire and the third electric wire with the insulating film. Features.

  According to this manufacturing method, the wiring board which can divide | segment the injection which a 2nd and 3rd electric wire receives from a 1st electric wire can be manufactured. Therefore, the second and third electric wires can reduce such injection. That is, the potential difference between the second and third wires can be reduced. Since the second electric wire and the third electric wire cross each other, for example, the potential of the second electric wire is high in the portion where the second electric wire is closer, and the third electric wire is in the portion where the third electric wire is close. The potential increases. The respective electric potentials cancel each other, and as a result, the injection to the second and third electric wires can be reduced. As a result, the influence on the second and third electric wires is reduced, and the life of elements such as the magnetic head connected to the wiring board and the wiring board can be improved. Can be provided. Further, the wiring board does not need to be restricted in sense current in consideration of injection, and can transfer a large amount of information. Therefore, the wiring board can cope with high-speed transfer.

  Further objects or other features of the present invention will become apparent in the preferred embodiments described with reference to the accompanying drawings.

  According to the wiring board according to the present invention, the second and third electric wires can divide the injection received from the first electric wire. Therefore, the second and third electric wires can reduce such injection. That is, the potential difference between the second and third wires can be reduced. When the second electric wire and the third electric wire are configured to cross each other, for example, the potential of the second electric wire is high in a portion where the second electric wire is closer, and the third electric wire is in a portion where the third electric wire is close. The potential of becomes higher. The respective electric potentials cancel each other, and as a result, the injection to the second and third electric wires can be reduced. As a result, the influence on the second and third electric wires is reduced, and it is possible to improve the life of the wiring board and the head connected to the wiring board, so that a wiring board with excellent maintainability is provided. Can do. Further, the wiring board does not need to be restricted in sense current in consideration of injection, and can transfer a large amount of information. Therefore, the wiring board can cope with high-speed transfer.

[Embodiment 1]
A wiring board according to a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a plan view showing an internal structure of a hard disk drive (HDD) 100 as a magnetic disk device having this wiring board. The HDD 100 is generally configured with a magnetic disk 110, a carriage 120, an actuator 130, and a spindle motor 140 inside a housing 150.

  The magnetic disk 110 is a disc-shaped recording medium in which a magnetic agent is applied to the surface of a silicon substrate or a glass substrate, and information recording / reproduction is performed by a magnetic head. In order to ensure a large recording capacity of the HDD 100, the magnetic disk 110 can be magnetically recorded by applying a magnetic agent on both the front and back surfaces, for example, and a plurality of magnetic disks 110 are stacked along a direction perpendicular to the paper surface in FIG. Have been used. As will be described later, one magnetic head is arranged on each front and back surface of each magnetic disk 110 so that magnetic recording / reproduction with respect to the magnetic disk 110 is possible.

  The carriage 120 is for moving the magnetic head to a desired position on the magnetic disk 110. The carriage 120 has a generally fan-shaped rigid arm portion 10 and a suspension portion 20 and is generally configured. As described above, when the magnetic layers are applied to both surfaces of the magnetic disk 110, the carriage 120 is arranged one by one corresponding to each surface. Further, when the magnetic disks 110 are stacked and arranged, a plurality of the carriages 120 are also arranged according to the number of stacked layers.

  As shown in FIG. 2, the rigid arm portion 10 has a suspension portion 20 fixedly held at its substantially fan-shaped tip, is fitted to a support shaft 30, and is rotatable about the support shaft 30. The support shaft 30 can be rotated by an actuator 130. The rigid arm portion 10 is configured to have a relatively high rigidity material and structure so that deformation and vibration are not caused by rotation.

  As shown in FIG. 3, the suspension portion 20 has a head mount portion 22 at the front end of a substantially fan-shaped main body portion 21 formed of a relatively low rigidity thin plate, and a slider 23 is attached to the head mount portion 22. And generally configured. As shown in FIG. 4, the slider 23 has a groove portion 23a and a taper portion 23b formed in a part of a substantially rectangular parallelepiped shape. A film-like magnetic head 24 having a head gap 24 a is joined to the slider 23.

  The slider 23 holds a film-like magnetic head 24. When the magnetic disk 110 is rotated by a spindle motor 140, which will be described later, an air flow generated by the rotation flows from the direction of arrow A into the groove portion 23a and the tapered portion 23b, and the air resistance causes the slider 23 and the magnetic head 24 to move to the surface of the magnetic disk 110. It is configured to float at a predetermined interval. Since the suspension part 20 is formed of a low-rigidity thin plate, the slider 23 and the magnetic head 24 are allowed to float by elastic deformation.

  The actuator 130 is for moving the magnetic head 24 to a desired position on the magnetic disk 110. The actuator 130 is configured by a controllable rotation drive device such as a stepping motor or a servo motor, and can control the rotation of the connected support shaft 30. The rigid arm portion 10 of the carriage 120 is fitted and fixed to the support shaft 30. Based on command information from a control circuit (not shown), the actuator 130 rotates by a desired rotation angle, whereby the rigid arm unit 10 also rotates by a desired angle, and the magnetic head 24 attached to the head mount unit 22 of the suspension unit 20 is attached to the magnetic disk. 110 to a desired position.

  The spindle motor 140 is for rotating / stopping the magnetic disk 110. In the HDD 100, magnetic recording / reproduction is performed while the magnetic disk 110 is rotated at a constant high speed by the spindle motor 140 and the magnetic head 24 is moved to a desired position on the magnetic disk 110. Ambient air is entrained by the high speed rotation of the magnetic disk 110 to form an air flow, which flows between the magnetic disk 110 and the slider 23 and causes the slider 23 to float from the surface of the magnetic disk 110 at a predetermined interval. As a result, the magnetic head 24 and the magnetic disk 110 do not contact and slide at the time of recording and reproduction, and the magnetic head 24 can be prevented from being burned.

  As shown in FIG. 3, the head mount portion 22 is provided with one end portion of an FPC (Flexible Printed Circuit board) 25. At one end thereof, a land 22a for connecting a write line extended from a recording head (write head) portion provided in the magnetic head 24 and a read line extended from a reproducing head (read head) portion. Are provided, and the write line and the read line are connected to the land 22a.

  The FPC 25 extends toward the rigid arm portion 10 along the surface 21 a of the main body portion 21, has a bent portion 25 a in front of the rigid arm portion 10, and the other end portion of the FPC 25 rotates to the side surface 21 b of the main body portion 21. (See also FIG. 2).

  A relay FPC 26 as a wiring board is attached from the side surface 21 b of the main body 21 to the side surface 10 a of the rigid arm unit 10. One end of the relay FPC 26 is electrically connected to the other end of the FPC 25, and the other end of the relay FPC 26 is electrically connected to the main FPC 12 attached to the base 11 of the rigid arm portion 10. The electrical signals of the write line and read line of the magnetic head 24 can be transmitted and received to the preamplifier IC 13 mounted on the main FPC 12.

  In the first embodiment, the relay FPC 26 as a wiring board is configured to electrically connect the FPC 25 and the main FPC 12, but the FPC need not necessarily be divided into three in this way. . The FPC 25 may be omitted, and the relay FPC 26 may directly transmit / receive a signal from the magnetic head 24 to / from the main FPC 12, or the relay FPC 26 may also serve as the main FPC 12.

  FIG. 5 is a plan view showing a wiring configuration of the relay FPC 26. The relay FPC 26 is provided with four electric wires, ie, two write lines (first electric wires) 26a and 26b, a read wire 26c as a second electric wire, and a read wire 26d as a third electric wire. Has been configured.

  Each of the four electric wires 26a to 26d has a head side land 26e for connecting to the FPC 25 and an amplifier side land 26f for connecting to the main FPC. In the head side land 26e, the write lines 26a and 26b are electrically connected to the anode side and the cathode side of the write line extended from the write head via the FPC 25. The reading lines 26c and 26d are electrically connected to the anode side and the cathode side of the reading line extended from the reading head via the FPC 25. As long as the write lines 26a and 26b are connected to the write head and the read lines 26c and 26d are connected to the read head, it is free to design whether they are connected to the anode side or the cathode side.

  The write lines 26a and 26b are wired in a straight line substantially in parallel on the path from the head side amplifier 26e to the amplifier side land 26f. In the first embodiment, read lines 26c and 26d are wired on one side (that is, on the lower side in FIG. 5) adjacent to the write lines 26a and 26b.

  At the time of writing by the HDD 100, a current of, for example, about 25 to 60 mA is passed through the write head provided in the magnetic head 24, so that the same level of current flows through the write lines 26a and 26b. . Due to this current, a magnetic field is generated around the write lines 26a and 26b, and the magnetic field causes injection to the read lines 26c and 26d wired adjacently.

  The influence of the injection is reversed depending on the polarity of the reading line. However, the injection changes according to the distance from the write lines 26a and 26b. That is, the influence of the injection is large when it is close to the write lines 26a and 26b, and the influence of the injection is small when it is far away.

  Therefore, for example, when the read lines 26c and 26d are linearly wired substantially in parallel in the path from the head side amplifier 26e to the amplifier side land 26f in the same manner as the write lines 26a and 26b, The injection for the reading line on the near side (for example, 26c) is larger than the injection for the reading line on the side far from the writing line (for example, 26d). The reading line 26c and the reading line 26d have opposite polarities. However, since the magnitudes of the injections are different, the reading lines 26c and 26d cannot cancel each other and cause a potential difference between the reading line 26c and the reading line 26d.

  While the current flowing through the reading lines 26c and 26d when reading the magnetic disk 110 is normally 2.4 to 3.4 mA, the current flowing through the writing lines 26a and 26b during writing is 25 times, which is about 10 times or more. Since it is about 60 mA, the injection due to the write current is a numerical value that cannot be ignored. This injection that occurs at the time of writing adversely affects the read lines 26c and 26d and the read head connected thereto, for example, reducing the life of the read head.

  However, in the relay FPC 26 according to the first embodiment, the reading line 26c and the reading line 26d intersect each other along the route as shown in FIG. On the side closer to the head side land 26e than the intersection 27, the read line 26c is wired close to the write lines 26a and 26b, and on the side closer to the amplifier side land 26f than the intersection 27, the read line 26d is written. It is wired close to the lead-in lines 26a and 26b.

  Therefore, on the side closer to the head side land 26e than the intersection 27, the read line 26c is more strongly affected by the injection by the write lines 26a and 26b, and on the side closer to the amplifier side land 26f than the intersection 27, The reading line 26d is more strongly affected by the injection of the writing lines 26a and 26b. Thereby, the influence of mutual injection can be offset and the influence of the injection which the reading lines 26c and 26d receive can be reduced. As a result, the life of the read head connected to the read lines 26c and 26d can be improved and the life can be extended.

  Here, in the relay FPC 26 according to the first embodiment, an intersection 27 is provided at a position corresponding to a length (L / 2) that is substantially half the length L thereof. The relay FPC 26 extends long in the length L direction, and a head side land 26e and an amplifier side land 26f are disposed at substantially both ends thereof. Therefore, the position of the intersection 27 is a position corresponding to approximately half the length of each of the electric wires 26a to 26d. With this configuration, the read line 26c is closer to the write lines 26a and 26b than the read line 26d, and the read line 26d is closer to the write lines 26a and 26b than the read line 26c. Therefore, the injection can be canceled efficiently. Therefore, the potential difference between the reading lines 26c and 26d due to the injection can be made substantially zero, and the life of the reading head or the like can be further improved.

  A manufacturing method for manufacturing the relay FPC 26 will be described with reference to FIG. 6 is a cross-sectional view of the relay FPC 26 cut along AA in FIG. First, the write lines 26a and 26b and the read line 26c are wired on the base layer 2 serving as a base material. The base layer 2 is made of an insulating resin material such as polyimide, and the electric wires 26a to 26d are made of a conductive material made of a metal such as copper. The write lines 26a and 26b and the read line 26c are wired so as to be separated from each other by a predetermined interval. The reading line 26c is bent in a crank shape so as to form an intersection 27 at the midpoint of the longitudinal path.

  An intersection insulating layer (insulating film) 4 is disposed from above the reading line 26c, and a reading line 26d is further provided thereon. Similarly to the reading line 26c, the reading line 26d is bent in a crank shape so as to form an intersection 27 at the midpoint of the longitudinal path. Therefore, at the intersection 27, the reading line 26c and the reading line 26d intersect so as to overlap in plan view (see FIG. 5), but since they are insulated by the intersection insulating layer 4, both the reading lines 26c, 26d is not short-circuited. The intersection insulating layer 4 exhibits its insulating function as long as it is disposed at least in the vicinity of the intersection 27. Of course, the intersection insulating layer 4 may be disposed over the entire length of the relay FPC 26 for convenience of the manufacturing process. . When all the electric wires 26 a to 26 d are wired, a cover layer (insulating film) 6 made of an insulating resin material is further disposed thereon, and each electric wire is covered with the cover layer 6.

[Embodiment 2]
In the first embodiment, a crank-shaped bent portion is formed on both the reading line 26c and the reading line 26d, and the intersection 27 is configured so that the bent portion and the bent portion overlap each other. However, as shown in FIG. 7 (a), the reading line 26c has a crank-shaped bent portion 28 formed substantially at the center in the length direction, and the reading line 26d extends from the head side land 26e toward the amplifier side land 26f. And may be configured to extend linearly.

  According to the second embodiment, the intersection 27 is formed by intersecting the reading line 26c so as to cross at a substantially central portion in the length direction of the reading line 26d. As schematically shown in FIG. 7B, the area of the region surrounded by the write line 26b and the read line 26c is defined as area S1, and the area of the region surrounded by the write line 26b and read line 26d is defined as the area. If S2 is configured so that the area S1 and the area S2 are substantially the same area, the influence of the injection from the writing line 26b to the reading line 26c and the influence of the injection to the reading line 26d are substantially the same, It is possible to effectively cancel the injection. Therefore, the potential difference between the reading lines 26c and 26d due to the injection can be made substantially zero, and the life of the reading head or the like can be further improved.

[Embodiment 3]
FIG. 8 shows a plan view of relay FPC 26 according to Embodiment 3 of the present invention. In the third embodiment, the write lines 26a and 26b are wired between the read line 26c and the read line 26d. The distance between the write line 26a and the read line 26c is arranged to coincide with the distance between the write line 26b and the read line 26d.

  With this configuration, the influence of the injection on the read line 26c from the write lines 26a and 26b and the influence of the injection on the read line 26d can be made substantially the same, and the injection can be canceled out. Become. Therefore, the potential difference between the reading lines 26c and 26d due to the injection can be made substantially zero, and the life of the reading head or the like can be further improved.

[Embodiment 4]
FIG. 9 is a plan view of relay FPC 26 according to Embodiment 4 of the present invention. In the third embodiment, read lines 26c and 26d are arranged between the write line 26a and the write line 26b. The distance between the write line 26a and the read line 26c is arranged to coincide with the distance between the write line 26b and the read line 26d.

  With this configuration, the influence of the injection on the read line 26c from the write lines 26a and 26b and the influence of the injection on the read line 26d can be made substantially the same, and the injection can be canceled out. Become. Therefore, the potential difference between the reading lines 26c and 26d due to the injection can be made substantially zero, and the life of the reading head or the like can be further improved.

[Embodiment 5]
10 and 11 show a relay FPC 26 according to Embodiment 5 of the present invention. 10 is a plan view thereof, and FIG. 11 is a cross-sectional view taken along the line BB in FIG. In the fifth embodiment, the read line 26c is wired so as to overlap the write line 26a, and the read line 26d is wired so as to overlap the write line 26b. The write lines 26a and 26b and the read lines 26c and 26d are insulated by an intermediate insulating layer (insulating film) 8.

  With this configuration, the distances between the read lines 26c and 26d and the write lines 26a and 26b can be matched, and the injection can be effectively canceled out. Therefore, the potential difference between the reading lines 26c and 26d due to the injection can be made substantially zero, and the life of the reading head or the like can be further improved.

  The present application further discloses the following matters.

(Supplementary Note 1) A first electric wire for transmitting a write signal, a second electric wire that is spaced apart from the first electric wire, and that is separated from the first electric wire, and is separated from the first electric wire. And a third electric wire for transmitting a read signal, the distance between the first electric wire and the second electric wire being set to be different from that of the second electric wire. There is at least one point that coincides with the distance between the first electric wire and the third electric wire. (1)
(Supplementary note 2) The wiring board according to supplementary note 1, wherein the second electric wire and the third electric wire intersect each other. (2)
(Supplementary Note 3) The length of the first electric wire corresponding to a portion where the second electric wire is closer to the third electric wire than the first electric wire, and the second electric wire is the above-mentioned first electric wire. The wiring board according to appendix 2, wherein the length of the first electric wire corresponding to a portion farther from the third electric wire is substantially the same length.

  (Additional remark 4) The area of the area | region enclosed by the said 1st electric wire and the said 2nd electric wire, and the area of the area | region enclosed by the said 1st electric wire and the said 3rd electric wire are substantially the same area. The wiring board according to appendix 2, characterized by:

  (Additional remark 5) The said 1st electric wire is arrange | positioned between the said 2nd electric wire and the said 3rd electric wire, The wiring board of Additional remark 1 characterized by the above-mentioned.

  (Supplementary note 6) The wiring board according to supplementary note 1, wherein the second electric wire and the third electric wire are disposed so as to overlap the first electric wire.

  (Appendix 7) The first electric wire is composed of at least two electric wires, and the second electric wire and the third electric wire are arranged between the two electric wires. Wiring board as described.

(Supplementary note 8) A head mechanism having the wiring board according to any one of supplementary notes 1 to 7. (3)
(Supplementary note 9) A magnetic disk device having the wiring board according to any one of supplementary notes 1 to 7. (4)
(Additional remark 10) It is a manufacturing method of the wiring board for transmitting a writing signal and a reading signal, Comprising: The process which cross | intersects the 2nd electric wire and 3rd electric wire for transmitting the said reading signal, Said 2nd A method for manufacturing a wiring board, comprising: a step of disposing an insulating film at a position where the electric wire and the third electric wire intersect; and a step of covering the second electric wire and the third electric wire with an insulating film. (5)

It is a top view which shows the internal structure of HDD which has the relay FPC which concerns on Embodiment 1 of this invention. FIG. 2 is an external perspective view showing a partially exploded schematic configuration of a carriage in the HDD shown in FIG. 1. It is an external appearance perspective view which shows the suspension part used for the carriage of FIG. FIG. 2 is an external perspective view of a slider used in the HDD shown in FIG. 1. It is a top view which shows the wiring structure of the relay FPC which concerns on Embodiment 1 of this invention. It is sectional drawing which cut | disconnected the relay FPC shown in FIG. 5 by AA in FIG. FIG. 5A shows a relay FPC according to a second embodiment of the present invention, FIG. 5A is a plan view showing a wiring configuration thereof, and FIG. 5B shows the size relationship of the area surrounded by the write line and the read line. It is a schematic diagram for demonstrating. It is a top view which shows the wiring structure of the relay FPC which concerns on Embodiment 3 of this invention. It is a top view which shows the wiring structure of the relay FPC which concerns on Embodiment 4 of this invention. It is a top view which shows the wiring structure of the relay FPC which concerns on Embodiment 5 of this invention. It is sectional drawing which cut | disconnected the relay FPC shown in FIG. 10 by BB in FIG.

Explanation of symbols

4: Intersection insulating layer (insulating film)
6: Cover layer (insulating film)
24: Magnetic head 26: Relay FPC (wiring board)
26a, 26b: Write line (first electric wire)
26c: Reading line (second electric wire)
26d: Reading line (third electric wire)
27: Intersection 100: HDD (magnetic disk device)
120: Carriage 130: Actuator

Claims (5)

A first wire for transmitting a write signal;
A second electric wire that is spaced apart from the first electric wire and transmits a read signal;
A third electric wire that is separated from the first electric wire and is wired at a different position from the second electric wire and transmits a read signal;
At least one point where the distance between the first electric wire and the second electric wire matches the distance between the first electric wire and the third electric wire is present.   The wiring board according to claim 1, wherein the second electric wire and the third electric wire intersect each other.   A head mechanism having the wiring board according to claim 1.   A magnetic disk device having the wiring board according to claim 1. A method of manufacturing a wiring board for transmitting a write signal and a read signal,
Crossing a second wire and a third wire for transmitting the read signal;
A step of disposing an insulating film at a position where the second electric wire and the third electric wire intersect;
And a step of covering the second electric wire and the third electric wire with an insulating film.

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