JP2006245121A - Method of manufacturing wiring member and flexure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a flexure which can perform simulation for deciding the outer shape of a supporting base material corresponding to a required spring characteristic, specifically, in further miniaturization of a recent wireless suspension, and in which a connection portion used in performing electrical connection with a control circuit by ultrasonic bonding is a member of a wireless suspension excellent in ultrasonic bonding performance, and to provide a method of manufacturing the flexure. <P>SOLUTION: In the wiring member in which wiring is formed on the supporting base material, the wiring consists of two or more wiring portions having different rigidity. The wiring further consists of a wiring portion consisting of an electrolytic copper foil and a wiring portion consisting of a rolled copper foil. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a wiring member used for various applications such as a magnetic head suspension assembly and a method of manufacturing a flexure that is a member of a wireless suspension for a magnetic head suspension assembly.

In recent years, for various applications such as for magnetic head suspension assemblies, etc., a wiring with a structure in which a support base, an insulating layer, and a wiring layer made of metal layers are laminated in this order, and each layer is etched into a predetermined shape for each purpose. A member is used.
For example, in Japanese Patent Laid-Open No. 2002-25213 (Patent Document 1), a wiring substrate is formed by a subtractive method using a laminated base material in which a metal layer, an insulating layer, and a conductive layer are laminated in this order. There is a description of a wireless suspension blank (hereinafter also simply referred to as a wireless suspension) for a magnetic head suspension, which is processed by an etching method and an insulating layer is processed by wet etching.
Japanese Patent Laid-Open No. 2000-49195 (Patent Document 2) does not specifically describe a method of manufacturing a wireless suspension blank for a hard disk drive (also referred to as an HDD). A manufacturing method is disclosed.
In this manufacturing method, as a laminate, a three-layer structure composed of metal foils laminated on both sides of a polyimide film is used, and a resist pattern is formed on each of the metal foils laminated on both sides of the polyimide film. After simultaneously etching the metal foil with an etching solution, the resist pattern was peeled off, and then the polyimide film was patterned by plasma etching using one metal foil as a mask, and then used as a mask. By removing the metal foil, a member for an electronic component which is a laminate of the patterned polyimide film and the patterned metal foil is obtained, and this manufacturing method also forms a wiring portion by a subtractive method. .
On the other hand, in Japanese Patent Laid-Open No. 2002-25026 (Patent Document 3), a laminated base material in which an insulating layer is disposed on a supporting base material made of a metal layer is used, and a wiring portion is formed on the insulating layer by a semi-additive method. There is a description of a method for manufacturing a wiring member that is formed, a metal layer is processed by an etching method, and an insulating layer is processed by wet etching.
JP 2002-25213 A JP 2000-49195 A In this case, the wireless suspension is a suspension for a magnetic head suspension that is not particularly a wire (coating wiring) drawn around the wire, and is usually a support base. A wiring layer is formed on a material via an insulating layer, and the wiring layer is formed from a metal layer by etching, plating, or the like.

In the case of the method of forming the wiring portion by the above-described subtractive method, the wiring is formed by etching a conductive layer (or a thin metal layer) that has been laminated in advance, and the same material is used throughout the formed wiring. .
As the conductive layer (or thin metal), either an electrolytic copper foil or a rolled copper foil is used.
Also, in the case of the method of forming the wiring portion by the semi-additive method described above, since the entire wiring is formed by plating, the same material is used throughout the entire wiring to be formed.
In brief, the semi-additive method is a processing method in which a metal part including a wiring part to be formed is formed by plating, and etching is further performed to form a wiring from the plated metal part. The subtractive method is a processing method for forming a wiring portion by selective etching of a metal layer that has been prepared in advance.
In general, the formation of wiring by the semi-additive method is excellent in miniaturization of wiring but is inferior in productivity compared to the formation of wiring by the subtractive method.

Recently, there is a strong demand for miniaturization of HDD magnetic head suspension assemblies, and further miniaturization of wireless suspensions is also demanded.
As a result, wireless suspensions that are particularly excellent in spring characteristics have been required.
With the miniaturization of wireless suspension, when the wiring layer is formed by using the rolled copper foil as a subtractive method, the rigidity of the rolled copper foil cannot be ignored, and the support base corresponding to the spring characteristics required for the wireless suspension. There has been a problem that the simulation for determining the outer shape of the material becomes difficult.
In addition, when the wiring layer is formed by the subtractive method using electrolytic copper foil as the material, or when the wiring layer is formed by the semi-additive method, to determine the outer shape of the support substrate corresponding to the spring characteristics In this simulation, the rigidity of the wiring can be ignored, which is advantageous in the simulation, but since the electrical connection between the wireless suspension and its control circuit is made by ultrasonic bonding, There is a problem that it is inferior in terms of ultrasonic bonding.
The electrical connection between the wireless suspension and its control circuit is usually made through a relay circuit unit for connecting them, but the wireless suspension and the relay circuit unit are electrically connected by ultrasonic bonding. After that, if a problem is found in the relay circuit section between the wireless suspension and its control circuit by inspection etc., the wireless suspension may be disconnected from the relay circuit section. However, the connection portion of the wireless suspension is required to have high rigidity.

As described above, recently, there is a strong demand for miniaturization of magnetic head suspension assemblies for HDDs, and there is a demand for further miniaturization of wireless suspensions. Simulation for determining the outer shape of the support base corresponding to the spring characteristics required for the suspension can be performed easily, and the connection part when performing electrical connection with the control circuit by ultrasonic bonding is ultrasonic bonding There was a need for an excellent wireless suspension.
The present invention is compatible with this, and in particular, when further miniaturizing a recent wireless suspension, it is possible to easily perform a simulation for determining the outer shape of the supporting base material corresponding to the required spring characteristics, and to provide a control circuit. It is intended to provide a flexure that is a member of a wireless suspension in which a connection portion when performing electrical connection with is excellent in ultrasonic bonding.
At the same time, it is intended to provide a method for producing such a flexure.

The wiring member of the present invention is a wiring member in which wiring is formed on a support base material, and the wiring is composed of two or more wiring portions having different rigidity.
And it is said wiring member, Comprising: The said wiring consists of two types, the wiring part which consists of electrolytic copper foil, and the wiring part which consists of rolled copper foil, It is characterized by the above-mentioned.
Further, in any one of the above wiring members, the supporting base material is made of a metal layer that exhibits spring characteristics, is externally processed into a predetermined shape, and forms the wiring via an insulating layer. It is characterized by this.
The wiring member according to claim 3, wherein the wiring member is a flexure that is a member of a wireless suspension for a magnetic head suspension assembly, and connects the slider and the control circuit by the wiring. The wiring part made of foil and the wiring part made of rolled copper foil are composed of two types, and at least an ultrasonic bonding connection part to the control circuit side of the wiring is formed with the rolled copper foil, and the slider side of the magnetic head suspension The tip end side is formed of an electrolytic copper foil, and the metal layer exhibiting the spring characteristics is made of stainless steel.

The manufacturing method of the flexure of the present invention comprises a metal layer that expresses spring characteristics, and a wiring part made of electrolytic copper foil and a rolled copper foil on a support base material that has been externally processed into a predetermined shape via an insulating layer Forming a wiring composed of two types with a wiring section made of, and forming an ultrasonic bonding connecting portion for making electrical connection with the control circuit side by ultrasonic bonding of the wiring with a rolled copper foil, A flexure manufacturing method for manufacturing a flexure, which is a member of a wireless suspension for a magnetic head suspension assembly, in which a tip end side which is a tip side of the magnetic head suspension of the wiring is formed of electrolytic copper foil. Then, in order, (A) an electrolytic copper foil and a rolled copper foil are laminated through an insulating core material layer to prepare a laminated substrate for wiring formation having a three-layer structure, and the laminated substrate On the other hand, a first photoetching step of forming the rolled copper foil into a predetermined shape by an etching method using a first resist platemaking, and (B) removing the resist in the first resist platemaking, An insulating layer on which the rolled copper foil is provided with an insulating layer and an adhesive layer in order, and a bonding step of bonding the metal layer through this,
(C) a second photoetching step of forming the electrolytic copper foil of the laminated base material into a predetermined shape by an etching method using a second resist platemaking; (D) removing the resist in the second resist platemaking; A third photoetching step for forming the core material layer into a predetermined shape by the etching method using the resist plate making, and (E) removing the resist in the third resist plate making and performing an etching method using the fourth resist plate making. The core material layer in the via connection portion formation region is perforated so as to reach the rolled copper foil side, or the insulating layer portion in the via connection portion formation region reaches the metal layer side together with the perforation. After perforating, the conductive material is arranged in each perforated hole, and the electrolytic copper foil side and the rolled copper foil side, or the electrolytic copper foil side, the rolled copper foil side, the rolled copper foil side, and the metal layer Electrically connecting and conducting, and (F) removing the resist in the fourth resist plate making, exposing the electrolytic copper foil side to a predetermined region including the ultrasonic bonding connection, A protective film forming step of covering with a protective film, (G) an outer shape processing step of performing an outer shape processing of the metal layer using the insulating layer portion as an etching stopper layer by an etching method using a fifth resist plate making, and (H) electrolysis Etching removal step of etching and removing the insulating layer portion in the exposed region and the core material layer immediately below it in a state where the copper foil side is covered with an etching resistant film, (I) A plating process is performed in which plating is performed on the exposed rolled copper foil surface and the exposed electrolytic copper foil surface, which are to be ultrasonic bonding connection portions, respectively.
And it is the manufacturing method of the said flexure, Comprising: The said metal layer is stainless steel, The core material layer of the said laminated base material, the said insulating layer, and an adhesive material layer are all consisting of a polyimide resin, It is characterized by the above-mentioned. Is.
Alternatively, the flexure manufacturing method of the present invention comprises a metal layer that expresses spring characteristics, and a rolled portion formed of electrolytic copper foil and rolled over a support base that has been externally processed into a predetermined shape via an insulating layer. Forming two types of wiring with a wiring section made of copper foil, and forming an ultrasonic bonding connection section with rolled copper foil for electrical connection with the control circuit side by ultrasonic bonding of the wiring In addition, manufacture of a flexure for manufacturing a flexure which is a member of a wireless suspension for a magnetic head suspension assembly, in which a tip end side which is a tip end side of the magnetic head suspension of the wiring is formed of electrolytic copper foil In order, (a) on one surface of the rolled copper foil, a wiring portion made of electrolytic copper foil is applied to the surface of the rolled copper foil, and the rolled copper foil is etched from the rolled copper foil side. Forming an electro-deposited copper foil wiring part forming step through an electrically conductive connection layer that becomes an etching stopper layer when etching, and (b) an insulating layer on the wiring part forming side made of the electro-deposited copper foil, (C) The rolled copper foil in the via connection portion forming region is provided with an insulating layer portion in which adhesive layers are arranged in order, and a bonding step of bonding the metal layer through the insulating layer portion. And the insulating layer portion of the via connection portion forming region is drilled so as to reach the metal layer side, and a conductive material is disposed in the drilled hole portion, and the rolled copper foil side and the metal A connecting step for electrically connecting and connecting the layer side; and (d) a rolled copper foil wiring portion forming step for forming a wiring portion made of a rolled copper foil by an etching method using resist plate making. And (e) a wiring portion made of electrolytic copper foil, a pressure A protective film forming step of exposing a predetermined region including an ultrasonic bonding connection portion and exposing a predetermined region including an ultrasonic bonding connection portion to a wiring side made of a copper foil, and (f) the insulating layer by an etching method using resist plate-making. An outer shape processing step of performing an outer shape processing of the metal layer using the portion as an etching stopper layer, and (h) the insulating layer portion in the exposed region in a state where the wiring side is covered with an etching resistant film. Etching removal step by etching, and (i) a plating step in which plating is performed on the exposed rolled copper foil surface and the exposed electrolytic copper foil surface to be the ultrasonic bonding connection portion, respectively. It is characterized by doing.
And it is a manufacturing method of the said flexure, Comprising: The said metal layer is stainless steel, and both the said insulating layer and an adhesive material layer consist of a polyimide resin, It is characterized by the above-mentioned.

(Function)
The wiring member according to claim 1 of the present invention can form a rigid wiring portion suitable for the purpose in each part or each region of the wiring member by adopting such a configuration.
Specifically, the wiring is composed of two types, ie, a wiring part made of electrolytic copper foil and a wiring part made of rolled copper foil. In this case, the wiring part made of electrolytic copper foil is miniaturized. In addition, the ultrasonic bonding property can be improved in the wiring portion made of the rolled copper foil.
Here, as the electrolytic copper foil, one having an elastic modulus of about 3 GPa (gigapascal) to 10 GPa, and as the rolled copper foil, one having an elastic modulus of about 100 GPa to 180 GPa is used.
In particular, the supporting substrate is made of a metal layer that exhibits spring characteristics, is externally processed into a predetermined shape, and forms the wiring via an insulating layer. The above arrangement of the wiring portions having different rigidity makes it possible to easily control the influence on the spring characteristics of the wiring.
In particular, the wiring member is a flexure that is a member of a wireless suspension for a magnetic head suspension assembly, and connects the slider and the control circuit by the wiring. The wiring includes a wiring portion made of electrolytic copper foil and rolled copper. It consists of two types of wiring parts made of foil, and at least an ultrasonic bonding connection part with the control circuit side of the wiring is formed of rolled copper foil, and the tip part side which becomes the slider side of the magnetic head suspension is electrolytic copper. By adopting the configuration of claim 4, which is formed of foil, the outer shape of the supporting base material corresponding to the required spring characteristics can be met in the further miniaturization of the recent wireless suspension. Can be easily simulated to determine the connection, and the electrical connection with the control circuit is made by ultrasonic bonding There has been possible to provide a wireless suspension with excellent ultrasonic bonding properties.
An example of the metal layer that exhibits spring characteristics is stainless steel.
The wiring member according to claim 4 or 5, further comprising: a wiring portion in which a microstrip circuit is formed with one of the electrolytic copper foil and the rolled copper foil as a signal layer and the other as a ground layer. It is also possible to adopt a configuration, and it is also possible to adopt a configuration in which the support base is the ground and the signal transmission path is sandwiched between the ground layers. By adopting such a configuration, the high frequency characteristics can be improved.

The flexure manufacturing method of the present invention has the above-described structure, and in particular, in the recent further miniaturization of the wireless suspension, the support base corresponding to the required spring characteristics can be met. Manufactures flexures that are members of wireless suspensions that can be easily simulated to determine the outer shape of the material, and have excellent ultrasonic bonding properties when connecting to the control circuit using ultrasonic bonding. It is possible to provide a manufacturing method of a flexure that can be performed.
Specifically, it consists of two types, a wiring part made of electrolytic copper foil and a wiring part made of rolled copper foil, where the rigidity of the wiring can be substantially ignored, and the rigidity of the wireless suspension tip side can be substantially ignored. Manufacture of a wiring member that produces electrolytic copper foil, and forms a wiring member in which the ultrasonic bonding connection part (also referred to as a terminal part) is bonded copper, and further uses a rolled copper foil from the peelability of the ultrasonic bonding connection part. It was possible to provide a method.

As described above, the present invention increases the degree of freedom in miniaturization of the wiring, improves the ultrasonic bonding property, and further, the support base material is made of a metal layer that exhibits spring characteristics. In this case, it is possible to control the influence of the wiring on the spring characteristics.
In particular, with the recent miniaturization of wireless suspension, it is possible to meet the demands for miniaturization of wiring, easily perform the simulation to determine the outer shape of the support base corresponding to the required spring characteristics, and the control circuit It is possible to provide a flexure, which is a member of a wireless suspension, in which a connection portion when performing electrical connection of the above by ultrasonic bonding is excellent in ultrasonic bonding properties.
At the same time, it is possible to provide a method for manufacturing such a flexure.

Embodiments of the present invention will be described with reference to the drawings.
FIG. 1 (a) is a schematic view showing the arrangement of the wiring and supporting base material in the first example of the embodiment of the wiring member of the present invention, and FIG. 1 (b) is a perspective view of FIG. 1 (a). FIG. 1 (c) is a diagram showing a cross section passing through B1-B2-B3 in FIG. 1 (a), and FIG. 2 (a) is a diagram showing a cross section passing through A1-A2-A3 of FIG. FIG. 2B is a schematic view illustrating the arrangement of the wiring and the supporting base material in the second example of the embodiment of the wiring member, and FIG. 2B is a cross section passing through A11-A21-A31 in FIG. 2 (c) is a view showing a cross section passing through B11-B21-B31 in FIG. 2 (a), and FIGS. 3 to 6 are views of the wiring member of the first example shown in FIG. FIGS. 7 to 9 are diagrams showing steps of the manufacturing method of the wiring member of the second example shown in FIG. 2, and FIG. 10 is another embodiment of the wiring member of the present invention. It is a figure for explaining an example .
In FIG. 1A and FIG. 2A, in order to make the state of the wiring easy to understand, between the support base material 170A (270A), the rolled copper foil wiring 130, and the electrolytic copper foil wiring 120, respectively. Although the insulating layer and the protective layer covering the wiring are not shown, in FIG. 1B, FIG. 1C, FIG. 2B, and FIG. Show.
3 to 6, (a) to (t) are states in a cross section passing through A1-A2-A3 in FIG. 1 (a), and (a1) to (t1) are B1 in FIG. 1 (a). -B2-B3 shows a state in a cross section, and (a1) to (t1) respectively correspond to (a) to (t) in a process.
Moreover, the cross-sectional views in FIGS. 7 to 9 are shown upside down from the cross-sectional views in FIGS. 2B and 2C for the sake of convenience.
Similarly, in FIGS. 7 to 9, (a) to (t) are states in a cross section passing through A11-A21-A31 in FIG. 2 (a), and (a1) to (t1) are FIGS. ) In a cross section passing through B11-B21-B31, (a1) to (t1) respectively correspond to (a) to (t) in a process.
1 to 10, 100 is a laminated base material, 110 is a core material layer, 120 is an electrolytic copper foil, 120A is a tip portion, 121 and 122 are electrolytic copper foil wirings, 121A is a connection opening, 121B is a connection portion, 130 is a rolled copper foil, 130A is a connection part (also referred to as a terminal part), 131-133 is a rolled copper foil wiring, 132A is a connection opening, 132B is a connection part, 141-143 is a connection part, 150 is an insulating layer part, 160 is a plating part, 170 is a metal layer, 170A is a support substrate, 181 to 186 are resists, 181A to 185A are openings of (resist), 190 is a cover layer (also referred to as a protective layer), 220 is an electrolytic copper foil, 220A , 221 and 222 are electrolytic copper foil wiring, 230 is rolled copper foil, 230A is a connection portion (also referred to as a terminal portion), 231 to 233 are rolled copper foil wiring, 232A is a connection opening, and 232B Connection parts, 241 to 243 are connection parts, 250 is an insulating layer part, 260 is a plating part, 270 is a metal layer, 270A is a support base, 281 to 184 are resists, 281A to 283A are (resist) openings, 290 is A cover layer (also referred to as a protective layer), 510 is a first wiring portion, 520 is a second wiring portion, and 530 is a third wiring portion.

First, the 1st example of embodiment of the wiring member of this invention is demonstrated based on FIG.
The wiring member of the first example has an insulating layer (insulating layer portion 150, core material layer) made of polyimide resin on a plate-like support base material 170 made of stainless steel that expresses a spring characteristic that is externally processed into a predetermined shape. 110) is a flexure that is a member of a wireless suspension for a magnetic head suspension assembly, in which wiring is formed via the wiring, and connects the slider and the control circuit by wiring. The wiring is formed by electrolytic copper foil 120 and rolled copper foil 130. The ultrasonic bonding connection portion (130A) at least with the control circuit side of the wiring is formed with the rolled copper foil 130, and the tip end portion which becomes the slider (not shown) side of the magnetic head suspension Side 120 </ b> A is formed of electrolytic copper foil 120.
In addition, the flexure which is the member of the wireless suspension which is the wiring member of this example is controlled via the relay wiring by ultrasonic bonding with the relay wiring for relaying to the control circuit side which controls the flexure. The electrical connection with the circuit side is made.
In the wiring member of the first example, a rolled copper foil ground plane is included by a subtractive method from a laminated structure base material in which a non-rigid electrolytic copper foil 120 and a rolled copper foil 130 are laminated via a core material layer 110. Each wiring is formed by etching.
In this example, a polyimide resin layer is used as the core material layer 110, and in this example, the support base material 170A is bonded to the support base material 170A side of the polyimide resin as the insulation layer in the present example. For this purpose, polyimide resins are sequentially laminated as an adhesive layer.
Note that the insulating layer and the adhesive layer forming the core material layer 110 and the insulating layer portion 150 are both made of polyimide resin, so that they are chemically, mechanically and electrically stable.
The cover layer 190 is also made of polyimide resin.
In this example, the connection between the electrolytic copper foil wiring 121 and the rolled copper foil wiring 131 is made at a connection portion 141 having a via structure provided between both wirings, and the electrolytic copper foil wiring 122 and the rolled copper foil. The connection with the wiring 133 is made at the connection portion 142 of the via structure provided between the two wirings, and the connection between the rolled copper foil wiring 132 and the supporting base material 170A is the connection of the via structure provided between the two wirings. Here, the rolled copper foil wirings 131 and 133 are connected to the signal wiring, and the rolled copper foil wiring 132 is connected to the ground.
The connection parts 141 to 143 are formed by plating electrolytic Cu or the like to be made conductive, or filled with a conductive paste or a resin mixed with conductive particles to be made conductive and electrically connected. is doing.

In the wiring member of the first example, the wiring is composed of a wiring portion made of non-rigid electrolytic copper foil (electrolytic copper foil wiring 121, 122) and a wiring portion made of rolled copper foil (rolled copper foil wiring 131-133). In the wiring portion made of the electrolytic copper foil, the degree of freedom of miniaturization is increased, and the ultrasonic bonding property is improved in the wiring portion made of the rolled copper foil.
In particular, the support substrate 170A is made of stainless steel that exhibits spring characteristics, is externally processed into a predetermined shape, and has a configuration in which a wiring is formed through the second insulating layer 150. The wiring has at least an ultrasonic wave. The bonding connection portion is formed of the rolled copper foil 130, and the tip portion 120A side which is the tip side of the magnetic head suspension is formed of the electrolytic copper foil 120. It is possible to easily meet the demands for miniaturization, to easily perform the simulation for determining the outer shape of the support substrate corresponding to the required spring characteristics, and to make electrical connection with the control circuit by ultrasonic bonding The connecting portion is excellent in ultrasonic bonding properties.
In particular, even in the recent miniaturization of wireless suspension, the spring characteristics as a wiring member can be easily controlled.

Next, an example of the manufacturing method of the wiring member of a 1st example is demonstrated based on FIGS.
First, a laminated base material 100 for wiring formation in which a non-rigid electrolytic copper foil 120 and a rolled copper foil 130 are laminated via an insulating core material layer 110 to have a three-layer structure is prepared. (Fig. 3 (a), Fig. 3 (a1))
Here, as the electrolytic copper foil 120, one having an elastic modulus of about 3 GPa (gigapascal) to 10 GPa, and as the rolled copper foil, one having an elastic modulus of about 100 GPa to 180 GPa is used.
As the rigidity of the rolled copper foil, one having good wire bonding properties, more preferably one that can withstand peeling of wire bonding is preferable.
The electrolytic copper foil is pure copper and has a lower rigidity than a rolled copper foil that is not 100% pure copper. Further, the thickness of the wiring layer is usually about 12 μm, but 9 μm to 8 μm is preferable in terms of thinning.
As a method for producing the electrolytic copper foil, for example, there are a method of depositing on a roll surface portion in a copper sulfate solution and peeling off the roll, and a method of directly depositing on a plate-shaped product portion.
In the latter case, Ni—Cr or the like is formed in advance as a seed layer by sputtering when forming on the insulating layer (corresponding to the core material layer 110).
The rolled copper foil is formed by rolling an ingot, as is well known.
As a method for forming the laminated base material 100, a method of press-bonding an electrolytic copper foil, a core material layer, and a rolled copper foil, or a pressure-bonding core material layer and a rolled copper foil to form a two-layer laminated base material, There is a method in which a seed layer is formed by sputtering on the surface of the core material layer that is not on the rolled copper foil side, and an electrolytic copper foil is further deposited on the seed layer.

Next, a first photoetching step is performed on the laminated base material 100 to form the rolled copper foil 130 in a predetermined shape by an etching method using a first resist plate making.
The resist 181 is disposed on both surfaces of the laminated base material 100 and is made into a shape that matches the shape of the rolled copper foil forming the resist 181 on the rolled copper foil 130, and the resist on the electrolytic copper foil 120 is left as it is (FIG. 3). (B), FIG. 3 (b1)), the rolled copper foil portion exposed from the opening 181A of the resist 181 is etched to form the rolled copper foil wirings 131 to 133 made of the rolled copper foil. 181 is removed. (FIG. 3 (c), FIG. 3 (c1))
Next, an insulating layer portion 150 in which a polyimide resin layer as an insulating layer and a polyimide resin layer as an adhesive layer are sequentially formed on the rolled copper foil side of the core material layer 110 is disposed (FIG. 3D, FIG. d1)), a metal layer 170 made of stainless steel is adhered and laminated thereon. (Fig. 3 (e), Fig. 3 (e1))
Here, stainless steel having a thickness of 0.18 mm is used as the support base material.
The resist 181 is not particularly limited as long as it has a desired resolution and appropriate processability, but a resist with good processability (for example, a dry film resist) is preferable.
Etching of the rolled copper foil is usually performed with a ferric chloride solution.

Next, a second photoetching step is performed to form the electrolytic copper foil of the laminated base material in a predetermined shape by an etching method using a second resist plate making.
The resist 182 is disposed on both surfaces of the base material on which the metal layer 170 is bonded and laminated, and is made into a shape that matches the shape of the electrolytic copper foil that forms the resist 182 on the electrolytic copper foil 120. The resist is left as it is (FIG. 3 (f), FIG. 3 (f1)), and the electrolytic copper foil wiring 121, 122 made of electrolytic copper foil is formed by etching through the electrolytic copper foil exposed through the opening 182A of the resist 182. After that, the resist 182 is removed. (Fig. 4 (g), Fig. 4 (g1))
The resist 182 is not particularly limited as long as it has a desired resolution and appropriate processability, but a resist with good processability (for example, a dry film resist) is preferable.
Etching of the electrolytic copper foil is usually performed with a ferric chloride solution.

Next, the exposed insulating core material layer 110 on the side of the electrolytic copper foil 120 of the laminated base material is formed into a predetermined shape by an etching method using a third resist plate making with respect to the base material from which the resist 182 has been removed. A third photoetching step to be formed is performed.
On the electrolytic copper foil 120 (wirings 121 and 122), the resist material 183 is formed in the shape of the core material layer 110 for forming the resist 183 by the third resist plate making (FIG. 4 (h), FIG. 4 (h1)). The core material layer 110 exposed from the opening 183A is etched and penetrated to form the core material layer 110 in a predetermined shape. (Fig. 4 (i), Fig. 4 (i1))
Here, the core material layer 110 is etched with an organic alkali made of polyimide resin.
Thereafter, the resist 183 is removed. (FIG. 4 (j), FIG. 4 (j1))
The resist 183 is not particularly limited as long as it has a desired resolution and appropriate processability, but a resist with good processability (for example, a dry film resist) is preferable.

Next, an insulating core material layer 110 is perforated so as to reach the rolled copper foil 120 side for forming a connection portion by etching using a fourth resist plate making, or at the same time, the insulating layer portion 150 is formed into a metal layer. 170 is drilled to reach the 170 side, and a conductive material is disposed in each hole, and the electrolytic copper foil 120 side and the rolled copper foil 130 side, or the electrolytic copper foil 120 side and the rolled copper foil 130 side, and the rolled copper. A connection step is performed in which the foil 130 side and the metal layer 170 side are electrically connected to conduct.
As described above, the connection portions 141 to 143 are made conductive by plating with electrolytic Cu or the like to fill, or made conductive by filling with a conductive paste or a resin mixed with conductive particles. And electrically connected.
After disposing the fourth resist 184 on both sides, the metal layer 170 side is left as it is, and an opening corresponding to the connection portion formed on the electrolytic copper foil 120 side is formed (FIG. 5 (k), FIG. 5 (k1)). ), The core base material 110 and the insulating layer 150 exposed from the resist opening 184A are each etched so as to reach the rolled copper foil 120 side or the metal layer 170 side. (FIG. 5 (l), FIG. 5 (l1))
Here, the core material layer 110 and the insulating layer 150 are both made of polyimide resin and etched with organic alkali.
The resist 184 is not particularly limited as long as it has a desired resolution and appropriate processability, but a resist with good processability (for example, a dry film resist) is preferable.
Then, a conductive material is arranged in each of the perforated holes, and the electrolytic copper foil 120 side and the rolled copper foil 130 side, or the electrolytic copper foil 120 side, the rolled copper foil 130 side, and the rolled copper foil 130 side, The metal layer 170 side is electrically connected to conduct. (Fig. 5 (m), Fig. 5 (m1))

Next, the resist 184 in the fourth resist plate making is removed, and a predetermined region including the ultrasonic bonding connection portion is exposed on the electrolytic copper foil 120 (wirings 121 and 122) side to form a protective film 190. (FIG. 5 (n), FIG. 5 (n1))
Next, the outer shape of the metal layer 170 is processed by the etching method using the fifth resist plate making using the insulating layer portion 150 made of polyimide resin as an etching stopper layer. (FIG. 5 (o) to FIG. 6 (p), FIG. 5 (o1) to FIG. 6 (p1))
As the etching solution for the metal layer 170, a ferric chloride solution is usually used.
The resist 185 is not particularly limited as long as it has a desired resolution and appropriate processability, but a resist with good processability (for example, a dry film resist) is preferable.

Next, after removing the resist 185 by the fifth resist plate making, the electrolytic copper foil 120 side is newly covered with the resist 186 which is an etching resistant film (FIG. 6 (q), FIG. 6 (q1) )), The insulating layer 150 in the exposed region and the core material layer 110 immediately below the insulating layer 150 are removed by etching. (FIG. 6 (r), FIG. 6 (r1))
The core material layer 110 and the insulating layer portion 150 are both made of polyimide resin and etched with organic alkali.
The resist 186 is not particularly limited as long as it has a desired resolution and appropriate processability, but a resist with good processability (for example, a dry film resist) is preferable.
Next, after removing the resist 186 (FIG. 6 (s), FIG. 6 (s1)), the exposed rolled copper foil surface and the exposed electrolytic copper foil surface, which are to be ultrasonic bonding connection parts, respectively, A plating process is performed. (FIG. 6 (t), FIG. 6 (t1))
As the plating, those having good ultrasonic bonding properties are preferable. Usually, known Ni plating and Au plating are performed in this order, but are not limited thereto.
In this way, the wiring member of the first example is formed.
In addition, the said manufacture example is one example and is not limited to this.

Next, a second example of the wiring member of the present invention will be briefly described with reference to FIG.
Similar to the first example, the wiring member of the second example has an insulating layer (insulating layer portion 250) on a plate-like support base material 270 made of stainless steel that exhibits a spring characteristic that is externally processed into a predetermined shape. Is a flexure that is a member of a wireless suspension for a magnetic head suspension assembly, in which wiring is formed via a wire, connecting a slider and a control circuit by wiring, and the wiring includes an electrolytic copper foil 220, a rolled copper foil 230, The ultrasonic bonding connecting portion (connecting portion 230A) at least with the control circuit side of the wiring is formed with the rolled copper foil 230, and the tip of the magnetic head suspension that becomes the slider (not shown) side The front end 220 </ b> A side that is the side is formed of the electrolytic copper foil 220.
And the connection part (241,242) of the wiring part which consists of an electrolytic copper foil, and the wiring part which consists of a rolled copper foil, and a conductive connection layer which consists of a wiring part in order, Ni layer, Au layer, Ni layer It is set as the laminated structure laminated | stacked through.
In addition, the flexure which is the member of the wireless suspension which is the wiring member of the second example is also connected via the relay wiring by ultrasonic bonding with the relay wiring for relaying to the control circuit side which controls the flexure. The electrical connection with the control circuit side is performed.
The wiring member of the second example is manufactured by the manufacturing process shown in FIGS. 7 to 9. In simple terms, the electrolytic copper foil 220 is formed on one surface of the rolled copper foil 230 according to the shape of the wiring to be formed. After the wiring portion made of is laminated via the conductive connection layer made of the Ni layer, the Au layer, and the Ni layer, which becomes an etching stopper layer when the rolled copper foil 230 is etched from the rolled copper foil 230 side, rolling is performed. The wiring portion made of the copper foil 230 is formed by etching.
In this example, the insulating layer portion 250 is formed by sequentially laminating polyimide resin as an adhesive layer for bonding the support base material 270A to the support base material 270A side of the polyimide resin as the insulating layer. .
The insulating layer and the adhesive layer that form the insulating layer portion 250 are both made of polyimide resin, so that they are chemically, mechanically, and electrically stable.
The cover layer 290 is also made of polyimide resin.
In this example, unlike the first example, the connection between the electrolytic copper foil wiring 221 and the rolled copper foil wiring 231 is made by a connecting portion 241 provided between the two wirings. 222 and the rolled copper foil wiring 233 are connected by a connecting portion 242 provided between the two wirings, and the connection between the rolled copper foil wiring 232 and the supporting base material 270A is a via structure provided between the two wirings. Here, the rolled copper foil wirings 231 and 233 are the side connected to the signal wiring, and the rolled copper foil wiring 232 side is the wiring connected to the ground.
In the connection portion 243 having a via structure, electrolytic Cu or the like is plated and filled to be conductive, or filled with a conductive paste or a resin mixed with conductive particles to be cured to be conductive. Connected to.

Next, an example of the manufacturing method of the wiring member of a 2nd example is demonstrated based on FIGS.
First, on one surface of the rolled copper foil 230, a conductive portion that becomes an etching stopper layer when etching the rolled copper foil from the rolled copper foil side is formed on the wiring portion made of the electrolytic copper foil 220 in accordance with the wiring shape to be formed. The layers are stacked through a connection layer.
In this example, a resist 281 having an opening 281A is formed on one surface of the rolled copper foil 230 (FIG. 7A) in accordance with the shape of the wiring to be formed by resist plate-making (FIG. 7B). Ni plating, Au plating, and Ni plating are formed on the opening 281A in order to a thickness of about 5 μm, 0.05 μm, and 0.5 μm, respectively, and then electrolytically used as a wiring portion. A copper foil 220 is plated on the opening 281A. (Fig. 7 (c))
The resist 281 is not particularly limited as long as it has a desired resolution and appropriate processability, but a resist with good processability (such as a dry film resist) is usually preferable.

Next, an insulating layer portion 250 in which an insulating layer and an adhesive layer are arranged in this order is provided on the wiring portion forming side made of the electrolytic copper foil 220 (FIG. 7D), and a metal layer 270 made of stainless steel is pasted thereon. Match. (Fig. 7 (e))
Next, the rolled copper foil 230 in the via structure connection part 243 formation region was perforated, and the insulating layer part 250 in the via structure connection part 243 formation region was perforated so as to reach the metal layer 270 side. A conductive material is disposed in the hole, and the rolled copper foil 230 side and the metal layer 270 side are electrically connected and conducted.
In this example, a resist plate 282 is provided with an opening 282A for forming a connection portion 243 having a via structure on the wiring side by resist plate-making (FIG. 7F), and the metal layer 270 is penetrated through the opening 282 by etching. . (Fig. 7 (g))
Next, the insulating layer 250 is opened from the opening 232A of the penetrating metal layer 270 so as to reach the metal layer 270 side (FIG. 8H), and a conductive material is disposed in the drilled hole, The rolled copper foil 230 side and the metal layer 270 side are electrically connected and conducted. (Fig. 8 (i))
The resist 282 is not particularly limited as long as it has a desired resolution and appropriate processability, but a resist with good processability (for example, a dry film resist) is usually preferable.
Next, after removing the resist 282 (FIG. 8 (j)), a wiring shape that forms a wiring portion made of the rolled copper foil 230 is formed by an etching method using resist plate making. (FIG. 8 (k)) to FIG. 8 (l))
The resist 283 is not particularly limited as long as it has a desired resolution and proper processability, but a resist with good processability (for example, a dry film resist) is usually preferable.
As an etching solution for the rolled copper foil 230, a ferric chloride solution is usually used.
Next, the wiring portion made of the electrolytic copper foil 220 and the wiring portion made of the rolled copper foil 230 are covered with a protective film 290 while exposing a predetermined region including the ultrasonic bonding connection portion. (Fig. 8 (m))
Next, the outer shape of the metal layer 270 is processed by the etching method using resist plate making the insulating layer portion 250 as an etching stopper layer, and the resist (not shown) is removed. (Fig. 9 (n))
Next, in a state where the wiring side is covered with an etching resistant film (resist 284),
The insulating layer 250 in the exposed region is removed by etching. (Fig. 9 (o))
The insulating layer portion 250 is a polyimide resin and is etched with an organic alkali.
The resist 284 is not particularly limited as long as it has a desired resolution and appropriate processability, but a resist with good processability (such as a dry film resist) is usually preferable.
Next, after removing the resist 284 (FIG. 9 (p)),
A plating process is performed in which plating is performed on the exposed rolled copper foil surface and the exposed electrolytic copper foil surface, which serve as ultrasonic bonding connection portions. (Fig. 9 (q))
As the plating, those having good ultrasonic bonding properties are preferable. Usually, known Ni plating and Au plating are performed in this order, but are not limited thereto.
In this way, the wiring member of the second example is formed.
In addition, the said manufacture example is one example and is not limited to this.
In some cases, in the method of manufacturing the wiring member of the second example, the rolled copper foil 230 in the via connection portion formation region is punched, and the insulating layer portion 250 in the via connection portion formation region reaches the metal layer 270 side. A process in which a conductive material is disposed in the perforated hole portion and the rolled copper foil 230 side and the metal layer 270 side are electrically connected to each other (this is referred to as a connection step). And the step of forming a wiring shape that forms a wiring portion made of rolled copper foil (this is referred to as a rolled copper foil wiring portion forming step) by an etching method using resist plate making may be reversed in order.

Further, as shown in FIG. 10A, as in the case of the wiring member of the second example, the first wiring portion 510 is composed of a first wiring portion 510 and a second wiring portion 520, and has different rigidity. In addition to the form in which the second wiring portion 520 is electrically connected by a conductive connection layer (not shown), as shown in FIG. The first wiring unit 510, the second wiring unit 520, and the third wiring unit 530 are connected to each other, and the first wiring unit 510 and the third wiring unit 530 are respectively connected to the second wiring unit 520. And a conductive connection layer (not shown) may be electrically connected.
In addition, as a manufacturing method in this case, the same process as the formation of the wiring part which consists of the electrolytic copper foil 120 in the manufacturing method shown in FIGS. 7-8, for example, the 1st wiring part 510, the 3rd wiring part Each of the 530 formations may be applied individually.
There may be a form having wiring composed of four or more wiring parts having different rigidity.

FIG. 1 (a) is a schematic view showing the arrangement of the wiring and supporting base material in the first example of the embodiment of the wiring member of the present invention, and FIG. 1 (b) is a perspective view of FIG. 1 (a). FIG. 1C is a diagram showing a cross section passing through B1-B2-B3 in FIG. 1A. FIG. 2 (a) is a schematic view showing the arrangement of the wiring and the supporting substrate in the second example of the embodiment of the wiring member of the present invention, and FIG. 2 (b) is a perspective view of FIG. 2 (a). FIG. 2C is a view showing a cross section passing through A11-A21-A31 of FIG. 2, and FIG. 2C is a view showing a cross section passing through B11-B21-B31 of FIG. It is the figure which showed a part of process of the manufacturing method of the wiring member of the 1st example shown in FIG. FIG. 4 is a diagram showing a part of a process of the method for manufacturing the wiring member of the first example shown in FIG. 1 following FIG. 3. It is the figure which showed a part of process of the manufacturing method of the wiring member of the 1st example shown in FIG. 1 following FIG. FIG. 6 is a diagram showing a part of a process of the method for manufacturing the wiring member of the first example shown in FIG. 1 following FIG. 5. It is the figure which showed a part of process of the manufacturing method of the wiring member of the 2nd example shown in FIG. FIG. 8 is a diagram showing a part of a process of the method for manufacturing the wiring member of the second example shown in FIG. 2 following FIG. 7. It is the figure which showed a part of process of the manufacturing method of the wiring member of the 2nd example shown in FIG. 2 following FIG. It is a figure for demonstrating the other example of a wiring member of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Laminated base material 110 Core material layer 120 Electrolytic copper foil 120A Tip part 121,122 Electrolytic copper foil wiring 121A Connection opening 121B Connection part 130 Rolled copper foil 130A Connection part (it is also called a terminal part)
131-133 Rolled copper foil wiring 132A Connection opening 132B Connection part 141-143 Connection part 150 Insulating layer part 160 Plating part 170 Metal layer 170A Support base material 181-186 Resist 181A-185A (Resist) opening 190 Cover layer (protection) Also called layer)
220 Electrolytic copper foil 220A Tip portions 221, 222 Electrolytic copper foil wiring 230 Rolled copper foil 230A Connection portion (also referred to as terminal portion)
231 to 233 Rolled copper foil wiring 232A Connection opening 232B Connection portion 241 to 243 Connection portion 250 Insulating layer portion 260 Plating portion 270 Metal layer 270A Support base material 281 to 184 Resist 281A to 283A (Resist) opening 290 Cover layer (protection) Also called layer)
510 1st wiring part 520 2nd wiring part 530 3rd wiring part

Claims (9)

  A wiring member in which wiring is formed on a supporting base material, wherein the wiring is composed of two or more wiring portions having different rigidity.   2. The wiring member according to claim 1, wherein the wiring is composed of two types of a wiring part made of electrolytic copper foil and a wiring part made of rolled copper foil.   3. The wiring member according to claim 1, wherein the supporting base material is made of a metal layer that exhibits spring characteristics, is externally processed into a predetermined shape, and the insulating base layer is interposed between the supporting member and the insulating member. A wiring member characterized by forming a wiring.   The wiring member according to claim 3, wherein the wiring member is a flexure that is a member of a wireless suspension for a magnetic head suspension assembly. The wiring connects a slider and a control circuit, and the wiring is made of an electrolytic copper foil. The wiring part and the wiring part made of rolled copper foil are composed of two types, and at least the ultrasonic bonding connection part with the control circuit side of the wiring is formed with the rolled copper foil, and the slider side of the magnetic head suspension is formed. A wiring member characterized in that the tip end side is formed of electrolytic copper foil.   The wiring member according to claim 4, wherein the metal layer that exhibits the spring characteristics is made of stainless steel. On the support base material which consists of a metal layer that expresses spring characteristics and is externally processed into a predetermined shape, the wiring part made of electrolytic copper foil and the wiring part made of rolled copper foil are interposed via an insulating layer. And forming an ultrasonic bonding connecting portion for making electrical connection with the control circuit side by ultrasonic bonding of the wiring with a rolled copper foil, and the tip of the magnetic head suspension of the wiring A flexure manufacturing method for manufacturing a flexure that is a member of a wireless suspension for a magnetic head suspension assembly in which a tip portion side that is a side is formed of an electrolytic copper foil, and in order, (A) electrolytic copper Foil and rolled copper foil are laminated via an insulative core material layer to prepare a laminated base material for wiring formation having a three-layer structure. Wherein the first photo-etching process for forming a rolled copper foil into a predetermined shape, the resist is removed in (B) a first resist plate-making by etching method,
By providing an insulating layer portion in which an insulating layer and an adhesive layer are arranged in order on the rolled copper foil side of the laminated base material, and a bonding step of bonding the metal layer through this, (C) by the second resist plate making A second photoetching step of forming the electrolytic copper foil of the laminated base material into a predetermined shape by an etching method; and (D) removing the resist in the second resist plate making, and by the etching method using a third resist plate making, A third photoetching step of forming a core material layer in a predetermined shape; and (E) removing the resist in the third resist plate making and etching the core in the via connection portion forming region by a fourth resist plate making method. After drilling the material layer so as to reach the rolled copper foil side, or after drilling the insulating layer portion in the via connection portion forming region so as to reach the metal layer side, together with the perforation, Conductive material is arranged in each opened hole, and the electrolytic copper foil side and the rolled copper foil side, or the electrolytic copper foil side, the rolled copper foil side, the rolled copper foil side, and the metal layer side are electrically connected. (F) removing the resist in the fourth resist plate making, exposing the electrolytic copper foil side to a predetermined region including the ultrasonic bonding connection portion, and covering with a protective film A protective film forming step, (G) an outer shape processing step for performing outer shape processing of the metal layer with the insulating layer portion as an etching stopper layer by an etching method using a fifth resist plate making, and (H) an electrolytic copper foil side An etching removal step of etching and removing the insulating layer portion in the exposed region and the core material layer immediately below the insulating layer portion in a state of being covered with an etching resistant film; Exposed to become sonic bonding connection Nobedohaku surface, the electrolytic copper foil surfaces are exposed, respectively, plated, flexure method for producing and performing a plating process.   It is a manufacturing method of the flexure of Claim 6, Comprising: The said metal layer is stainless steel, The core material layer of the said laminated base material, the said insulating layer, and an adhesive material layer are all consisting of a polyimide resin. A feature of the flexure manufacturing method.   On the support base material which consists of a metal layer that expresses spring characteristics and is externally processed into a predetermined shape, the wiring part made of electrolytic copper foil and the wiring part made of rolled copper foil are interposed via an insulating layer. And forming an ultrasonic bonding connecting portion for making electrical connection with the control circuit side by ultrasonic bonding of the wiring with a rolled copper foil, and the tip of the magnetic head suspension of the wiring A flexure manufacturing method for manufacturing a flexure that is a member of a wireless suspension for a magnetic head suspension assembly, in which a tip portion side that is a side is formed of electrolytic copper foil, and in order, (a) rolling On one side of the copper foil, in accordance with the shape of the wiring to be formed, the wiring part made of electrolytic copper foil is used as an etching stopper layer when the rolled copper foil is etched from the rolled copper foil side. An electrolytic copper foil wiring part forming step formed by stacking via a conductive connection layer, and (b) an insulating layer part in which an insulating layer and an adhesive layer are arranged in this order on the wiring part forming side made of electrolytic copper foil And a bonding step of bonding the metal layer therethrough, and (c) punching the rolled copper foil in the via connection portion formation region, and forming the via connection portion The insulating layer portion of the region is perforated so as to reach the metal layer side, a conductive material is disposed in the perforated hole portion, and the rolled copper foil side and the metal layer side are electrically connected. Conducting a connection step, and (d) a rolled copper foil wiring portion forming step for forming a wiring shape for forming a wiring portion made of a rolled copper foil by an etching method using resist plate making, and further sequentially ( e) A wiring portion made of electrolytic copper foil and a wiring portion made of rolled copper foil are subjected to ultrasonic treatment. A protective film forming step of exposing a predetermined region including a bonding connection portion and covering with a protective film; and (f) an external processing of the metal layer using the insulating layer portion as an etching stopper layer by an etching method using resist plate-making. (H) an etching removing step of etching and removing the insulating layer portion in the exposed region in a state where the wiring side is covered with an etching-resistant film; A method for producing a flexure, comprising performing a plating step in which plating is performed on an exposed rolled copper foil surface and an exposed electrolytic copper foil surface serving as an ultrasonic bonding connection portion. 9. The method of manufacturing a flexure according to claim 8, wherein the metal layer is stainless steel, and the insulating layer and the adhesive layer are both made of polyimide resin.

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