Multilayer printed wiring board and process for producing the same
At least one base material having a wiring circuit that has been formed into a predetermined outer shape is bonded to a motherboard. The motherboard wiring board and the base material having a wiring circuit are electrically connected to each other at least one portion through an inner via hole. The outer shape of the base material having a wiring circuit is smaller than the outer shape of the motherboard, with the base material having a wiring circuit having an island shape on the motherboard.
The present invention relates to a multi-layer wiring board and a method for manufacturing the same.
BACKGROUND ARTRecent electronic apparatuses have been made smaller and light weight in addition to developments in the applicability to high-frequency signals and digitized devices, and along with these developments, there have been demands for small-size devices, a high-density packaging property and the like in printed circuit boards being installed in the electronic apparatuses.
There is a rigid flex printed circuit board satisfying these demands which includes a rigid portion and a flex portion (for example, Japanese Patent Application Laid Open Publication No. 2002-158445).
With reference to
As shown in
Substantially, as shown in
Next, as shown in
Lastly, the micro-joints (for example, 103c), which have joined a rigid portion B and a flex portion A to the frame member (for example, 103b), are simultaneously punched out by using a die so that a rigid flex printed circuit board 110, shown in
Moreover, those circuit boards having an arrangement in which a built-up layer is formed on the surface layer of the rigid flex printed circuit board, and interlayer-connected thereto through IVHS (Interstitial Via Holes) and SVHS (Surface Via Holes) have also been proposed.
DISCLOSURE OF INVENTIONHowever, according to the conventional rigid flex printed circuit board and the manufacturing method thereof, after the lamination of the rigid portion, the outer shapes of the rigid portion and the flex portion need to be simultaneously cut out (a cutting process). Therefore, it is necessary to use substrates having sufficient margin portions required for positioning processes for the respective substrates. Moreover, in most of cases, after the cutting process, these margin portions are disposed as the frame members. In other words, in the conventional rigid flex printed circuit board, since the rigid portion needs to be laminated at a predetermined position of the flex substrate, assembling processes of the rigid portions on the inner layer and outer layer rigid substrates, which are carried out so as to place the rigid portions at predetermined positions on the flex substrate when formed as laminated layers, are limited by factors such as an outer shape and positions of the flex substrate. In other words, even when an attempt is made so as to carry out a laminating process only on one portion of the flex substrate, it is necessary to prepare an assembling-use member that is as large as the flex substrate.
For this reason, excessive multi-layered areas exist on the rigid portion, causing wasteful material costs. Further, there is a limitation in positions in which multi-layered areas are placed, resulting in little design freedom for wiring.
The present invention has been devised to solve the above-mentioned problems, and the first objective thereof is to provide a multi-layer wiring board which provides higher design freedom for wiring, and makes it possible to cut material costs, and also to reduce the substrate capacity, and a manufacturing method for such a wiring board.
In order to achieve the above-mentioned objects, according to a first aspect of a multi-layer wiring board, wherein at least one base material with wiring circuit being preliminarily formed into a predetermined outer shape is bonded to a motherboard, and the base material on the motherboards are electrically connected to each other through at least an inner via hole.
Moreover, conventionally, when a substrate that includes a plurality of substrates with single-sided wiring circuits is bent, a separation tends to occur between the substrates due to inter-layer stress of the layers of the motherboard printed substrate and the substrate with single-sided wiring circuits or between the layers of the laminated substrates with single-sided wiring circuits.
Therefore, a second object of the present invention is to provide a multi-layer wiring board which has higher anti-bending strength (peel strength) as compared with the conventional substrate, and a manufacturing method for such a wiring board
In order to achieve this objective, according to a second aspect of a multi-layer wiring board, wherein two or more substrates, each of which has been preliminarily formed into a predetermined outer shape with single-sided wiring circuit formed thereon, are laminated and bonded to a motherboard, and at least one inter-layer portion thereof is electrically connected through an inner via hole, and in this arrangement, the two or more laminated substrates, each with single-sided wiring circuit formed thereon, are positioned in a manner so as to place the outer shape of a second substrate bonded to the first substrate inside the outer shape of the first substrate being bonded to the motherboard side
Moreover, in the case when a circuit substrate that allows double-sided assembling processes is formed by using the conventional manufacturing method, a double-sided circuit substrate is required as a core substrate. In the case, however, as described above, upon forming a conductive pattern, most of the conductive layer on one side needs to be removed, resulting in wasteful use of materials and resources. Another problem is that complex manufacturing processes are required to form through holes and the like.
Therefore, a third object of the present invention is to provide a circuit substrate that allows double-sided packaging processes so that electronic parts can be assembled on double sides by using a single-sided circuit substrate as a core substrate (main circuit substrate), that is, as a motherboard
In order to achieve this object, according to a third aspect of a multi-layer wiring board, wherein at least one portion of an insulating base material of a main single-sided circuit substrate having a conductive pattern on one surface of the insulating substrate is partially removed so that the rear face of the conductive pattern is exposed at the removed portion, and from the other side of the insulating base material of the main single-sided circuit substrate, an electronic part is laminated with the main single-sided circuit substrate with the rear-face exposed portion of the conductive pattern of the main single-sided circuit substrate is electrically connect with the electrical part, and/or a single-sided circuit board for multi-layer wiring board having an interlayer conductive portion and a conductive pattern formed on one face of an insulating base material is laminated with the main single-sided circuit substrate with the rear-face exposed-portion of the conductive pattern is electrically connect with the single-sided circuit board for multi-layer wiring board.
Furthermore, the conventional printed wiring board that allows double-sided packaging processes uses a double-sided copper coat laminated plate (double-sided CCL) as a starting member for a relay board. In this technique, however, since plated through holes are used, time-consuming complex metal plating processes are required, and the thickness of a copper foil of the double-sided CCL tends to increase, causing the problem that it is difficult to form a fine pattern through chemical etching. Moreover, it is difficult to form a via hole to the upper layer or the like right above a through hole, and circuit designing is, ipso, restricted.
In order to solve this problem, a fourth object of the present invention is to provide a multi-layer wiring board that allows double-sided packaging processes so that electronic parts can be assembled on double sides by using a base material with single-sided circuit substrate formed thereon as a starting member for a relay board, and a manufacturing method for such a multi-layer wiring board
In order to achieve this object, according to a fourth aspect of a multi-layer wiring board, a multi-layer wiring board having wiring board for partial multi-layers formed on a specific area in a relay board formed by a base material with single-sided wiring circuit, and the relay board has a conductive layer on one face of an insulating substrate, an interlayer connecting portion comprising a via hole formed on the insulating substrate and filled with a conductive substance, and an interlayer connecting portion comprising a via hole formed on the insulating resin layer, and wherein the multi-layer-use substrates are laminated on respective specific areas on the face on the side opposite to the conductive layer face of the insulating base material and the surface of the insulating resin layer with, in conductive-association with the relay board.
BRIEF DESCRIPTION OF DRAWINGS
With reference to Figures, embodiments of the present invention will be described below.
First Embodiment
The partial wiring boards 20 are formed as follows: a plurality of resin base materials 21 with single-sided wiring circuits accordingly, which have outer shapes that have been formed into predetermined shapes that are smaller than the outer shape of the motherboard 10, are positioned on the surface and rear surface of the motherboard 10, and then colaminated. Here, the partial wiring boards 20 may include resin base materials with double-sided wiring circuits
The motherboard 10 is provided with an insulating base material 11 and conductor layers (wiring circuits) 12 formed on the surface and rear surface of the insulating base material 11. The insulating base material 11 of the motherboard 10 is made from a flexible resin such as polyimide. Additionally, with respect to the flexible resin, other materials, such as liquid crystal polymer (LCP), polyether imide (PEI), polyether ether ketone (PEEK), polyethylene naphthalate (PEN), polyethylene terephthalate (PET) and polyether sulfone (PES), may be used. The resin base material 21 with single-sided wiring circuit is provided with an insulating base material 22, and a conductor layer (wiring circuit) 23 formed on one surface of the insulating base material 22. Besides rigid prepreg, the insulating base material 22 of the resin base material 21 with single-sided wiring circuit may be made from a flexible resin such as polyimide.
The conductor layers 23 of the resin base materials 21 with single-sided wiring circuits formed into a multi-layer structure, as well as the conductor layers 23 of the resin base materials 21 with single-sided wiring circuits and the conductor layer 12 of the motherboard 10, are electrically connected to each other by a conductor 25 being filled with conductive paste and the like coating inner via holes (via hole) 24 are respectively formed in the resin base materials 21 with single-sided wiring circuits.
The multi-layer wiring board is manufactured by layering the resin base materials 21 with single-sided wiring circuits that have outer shapes that have been formed into predetermined shapes to one portion of the surface and/or the rear surface of the motherboard 10. More specifically, a build-up method in which the resin base materials 21 with single-sided wiring circuits are bonded to one after another sheet by sheet may be used, however, a colamination method in which a plurality of resin base materials 21 with single-sided wiring circuits, each of which has a wiring circuit and a via hole formed thereon, and has an outer shape that has been formed into a predetermined shape, are superposed on the surface or one portion of the rear surface of the motherboard 10, and bonded to one after another by heating and pressing these through a batch process is more preferably used since it is a simpler method and can be achieved at low costs.
The mutual layering process between the resin base materials 21 with single-sided wiring circuits, the layering process between the resin base materials 21 with single-sided wiring circuits and the motherboard 10 can be carried out by a layering layer (not shown) being formed on an overside opposite to the conductor layer 23 of the insulating base material 22 of each of the resin base materials 21 with single-sided wiring circuits. In the case when the insulating base material 22 of each of the resin base materials 21 with single-sided wiring circuits is made from a material having an adhesive property, such as thermoplastic polyimide, thermoplastic polyimide to which a thermosetting property is imparted or liquid crystal polymer, the above-mentioned layering layer can be omitted.
With these arrangements, electronic-component-packaging-use multi-layer-forming portions (partial wiring boards 20) can be freely placed on desired positions on the surface of the motherboard 10, and it becomes possible to reduce excessive multi-layer-forming portions, and consequently to greatly cut the material costs.
In particular, in the case when the electronic-part packaging portions are made from an expensive material such as polyimide in response to requirements such as better dielectric properties, light weight and thinness, the above-mentioned arrangements exert greater effects.
Moreover, in the above-mentioned substrate structures, the insulating layer (insulating base material 22) of the partial wiring board 20 performing as an electronic part packaging portion and the insulating layer (insulating base material 11) of a flex portion (motherboard 10) are preferably made from the same material so that the thermal and mechanical properties of the two layers are made coincident with each other, and therefore, it becomes possible to provide high reliability in thermal and mechanical properties.
In general, the motherboard 10 is coated with a cover layer or a solder resist to protect the conductor layer. With respect to the covering layer of the motherboard 10, an opening portion is preliminarily formed at a portion on which multiple layers are formed by the resin base materials 21 with single-sided wiring circuits, and the resin base materials 21 with single-sided wiring circuits may be bonded onto this opening portion. In this case, as shown in
Therefore, in this case, the exposed portion is coated with noble metal 15 such as gold as shown in
Moreover, as shown in
Furthermore, in an attempt to simplify processes, as shown in
Moreover, the inner via hole 24 having a structure as shown in
Next, with reference to
By using a polyimide base material 50 with single-sided copper foil 52 placed on one surface of a polyimide base material 51 as shown in
Next, as shown in
Here, the three-layer structure of the copper foil 52, the polyimide base material 51 and the adhesive layer 54 has an asymmetrical structure with respect to the surface and the rear surface thereof so that it is preferable to prevent undesired warping from occurring in the succeeding processes after the formation of the layering layer. Moreover, the adhesive layer 54 is preferably set to have a glass transition temperature of not more than 110° C. and a normal-temperature elastic modulus of not more than 1300 MPa.
Next, as shown in
Here, when a carbon dioxide laser, by using an excimer laser or the like, it becomes possible to carry out the processes at higher speeds. Moreover, with respect to the desmear method, a wet desmear process using permanganate is also generally used.
With respect to the IVH filling conductive paste, in addition to silver paste, various metal pastes, such as copper paste, carbon paste and nickel paste, may be used.
Next, as shown in
Referring to
As shown in
Thereafter, these members are subjected to heating and pressing processes with a vacuum heat pressing machine under a degree of vacuum of not more than 1 kPa so that a substrate 63 containing a Iti-1a er portion 64 as shown in
Here, upon carrying out the batch laminating processes, the resin base materials 57 with single-sided wiring circuits have an outer shape that has been formed into a predetermined shape may be laminated on the motherboard sheet by sheet, or after a plurality of the resin base materials 57 with single-sided wiring circuits have been preliminarily laminated, the laminated substrates may be placed on the motherboard through the batch process.
The positioning process may be carried out through a pin alignment method or an image recognition method. However, since the pin alignment method requires a space used for forming a pin hole, the positioning process using the image recognition is preferably adopted.
Next, as shown in
With reference to
As shown in
With respect to the positioning process in the modified example also, the positioning process using the image recognition is preferably adopted.
After the positioning process, these members are subjected to heating and pressing processes by a vacuum heat pressing machine under a degree of vacuum of not more than 1 kPa so that a substrate 71 as shown in
First Embodiment-Second Modified Embodiment
Referring to
As shown in
As shown in
Next, as shown in
In this manner, in accordance with the manufacturing method for the multi-layer substrate of the first embodiment, it is possible to form a circuit that has a multi-layer portion having a desired thickness at a desired position. Here, with respect to the resin base material with single-sided wiring circuit, those having a conductor layer with a thickness of approximately 8 to 18 μm and an insulating base material with a thickness of 25 to 100 μm are generally used.
Second EmbodimentWith reference to attached Figures, a second embodiment of the present invention will be described below.
In the multi-layer wiring board of the present embodiment, at a plurality of portions on the surface and rear surface of a motherboard (base material) 210, partial wiring boards (multi-layer portions) 220, which have outer shapes that have been preliminarily formed into predetermined shapes, are bonded so as to form an island shape. Here, the island shape is defined as a state in which the peripheral sides of the partial wiring boards 220 are not coincident with the peripheral sides of the motherboard 210 so that the partial wiring boards 220 are placed inside the area determined by the peripheral sides of the motherboard 210. Here, the predetermined shapes are determined by requirements in designing the motherboard.
The partial wiring boards 220 are formed as follows: a plurality of resin base materials 221A, 221B and 221C with single-sided wiring circuits accordingly, which have outer shapes that have been formed into predetermined shapes that are smaller than the outer shape of the motherboard 210, are laminated on the surface and rear surface of the motherboard 210 in succession through a batch process.
As shown in
In other words, the following relationship is satisfied: (area of resin base material 221A)>(area of resin base material 221B)>(area of resin base material 221C). More specifically, as shown in
The motherboard 210 is provided with conductor layers (wiring circuits) 212 formed on the surface and rear surface of an insulating base material 211. The insulating base material 211 of the motherboard 210 is made from a flexible resin such as polyimide. Additionally, with respect to the flexible resin, other materials, such as liquid crystal polymer (LCP), polyether imide (PEI), polyether ether ketone (PEEK), polyethylene naphthalate (PEN), polyethylene terephthalate (PET) and polyether sulfone (PES), may be used. Each of the resin base materials 221A, 221B and 221C with respective single-sided wiring circuits is provided with a conductor layer (wiring circuit) 223 formed on one surface of an insulating base material 222. The insulating base material 222 of each of the resin base materials 221 with single-sided wiring circuits may also be made from a flexible resin such as polyimide. The insulating base material 211 of the motherboard 210 and the insulating base material 223 of each of the resin base materials 221A, 221B and 221C with single-sided wiring circuits are preferably made from the same material such as polyimide from the viewpoints of thermal and mechanical influences.
The conductor layers 223 of the resin base materials 221A, 221B and 221C with single-sided wiring circuits, as well as the conductor layers 223 of the resin base materials 221 with single-sided wiring circuits and the conductor layer 212 of the motherboard 210, are electrically connected to each other by conductive paste 225 being filled in inner via holes (via holes) 224 respectively formed in the resin base materials 221 with respective single-sided wiring circuits.
This multi-layer wiring board in accordance with the second embodiment is manufactured by layering the resin base materials 221A, 221B and 221C with single-sided wiring circuits that have outer shapes that have been formed into predetermined shapes to one portion of the surface and/or the rear surface of the motherboard 210. More specifically, a build-up method in which the resin base materials 221 with single-sided wiring circuits are bonded to one after another sheet by sheet or a colamination method may be used. Here, the colamination method, which has an arrangement in which the resin base materials 221A, 221B and 221C with respective single-sided wiring circuits, each of which has a wiring circuit and a via hole formed thereon, and has an outer shape that has been formed into a predetermined shape, are superposed on one portion of the surface and/or the rear surface of the motherboard 210, and bonded to one after another by heating and pressing these through a batch process, is more preferably used since it is a simpler method and can be achieved at low costs. Additionally, the batch laminating process can be executed, after resin base materials with single-sided wiring circuits having an outer shape that has been formed into a predetermined shape have been laminated on the motherboard sheet by sheet, or it can be executed after a plurality of the resin base materials with single-sided wiring circuits have been preliminarily laminated, and placed on the motherboard.
The mutual layering processes between the resin base materials 221A, 221B and 221C with single-sided wiring circuits and the layering processes between the resin base materials 221A, 221B and 221C with single-sided wiring circuits and the motherboard 210 can be carried out by forming a layering layer (not shown) on a surface on the side opposite to the conductor layer 223 of the insulating base material 222 of each of the resin base materials 221A, 221B and 221C with single-sided wiring circuits and by using this layering layer.
In the case when the insulating base material 222 of each of the resin base materials 221A, 221B and 221C with single-sided wiring circuits is made from a material having an adhesive property, such as thermoplastic polyimide, thermoplastic polyimide to which a thermosetting property is imparted or liquid crystal polymer, the above-mentioned layering layer can be omitted.
With these arrangements, electronic-component-packaging-use multi-layer-forming portions (partial wiring boards 220) can be freely placed on desired positions on the surface of the motherboard 210, and it becomes possible to reduce excessive multi-layer-forming portions, and consequently to greatly cut the material costs.
In particular, in the case when the electronic-part packaging portions are made from an expensive material such as polyimide in response to requirements such as better dielectric properties, light weight and thinness, the above-mentioned arrangements exert greater effects.
Moreover, in the above-mentioned substrate structures, the insulating layer (insulating base material 222) of the partial wiring board 220 performing as an electronic part packaging portion and the insulating layer (insulating base material 211) of a flex portion (motherboard 210) are preferably made from the same material so that the thermal and mechanical properties of the two layers are made coincident with each other, and therefore, it becomes possible to provide high reliability in thermal and mechanical properties.
In this arrangement, the resin base materials 221A, 221B and 221C with single-sided wiring circuits that have been laminated on the motherboard 10 have a pyramid shape, and therefore, when the motherboard 210 is bent as schematically shown in
With this arrangement, stress concentration is alleviated so that the anti-separation strength (peel strength) is improved, thereby making it possible to provide a multi-layer wiring board having high anti-bending strength. In particular, a superior bending property, which is a feature of the multi-layer flexible printed wiring board (FPC), is properly exerted so that the features of the multi-layer flexible printed wiring board are exerted to the maximum.
Next, referring to
By using a polyimide base material 250 having single-sided copper foil 252 placed on one surface of a polyimide base material 251 as shown in
Next, as shown in
Here, the three-layer structure of the circuit portion (copper foil) 253, the polyimide base material 251 and the adhesive layer 254 has an asymmetrical structure with respect to the surface and the rear surface thereof so that it is preferable to prevent undesired warping from occurring in the succeeding processes after the formation of the layering layer. Moreover, the adhesive layer 254 is preferably set to have a glass transition temperature of not more than 110° C. and a normal-temperature elastic modulus of not more than 1300 MPa.
Next, as shown in
Here, by using a carbon dioxide laser, an excimer laser or the like, it becomes possible to carry out the processes at higher speeds. Moreover, with respect to the desmear method, a wet desmear process using permanganate is also generally used With respect to the IVH filling conductive paste, in addition to silver paste, various metal pastes, such as copper paste, carbon paste and nickel paste, may be used.
After filling the conductive paste, the conductive paste 256 is provisionally cured at 60° C. to 140° C. for 0.5 to 2 hours. Thus, the conductive paste 256 is cured to have a hardness of not less than 2B on the basis of pencil hardness, thereby making it possible to prevent coming off or deformation of the paste during a die-releasing process or a packaging process, which will be described later.
Next, as shown in
With reference to
As shown in
Next, a batch pressing process is carried out on the motherboard FPC 270, the resin base materials 261A, 261B and 261C by a vacuum heat pressing machine under a degree of vacuum of not more than 1 kPa so that a substrate containing a multi-layer portion 280 as shown in
Upon positioning the respective resin base materials 261A, 261B and 261C, rather than adopting a pin-alignment method that requires a space used for forming a pin hole, a positioning process using image recognition is more preferably adopted.
Next, as shown in
By repeating the processes shown in FIGS. 1 9A to 19C, the aforementioned multi-layer wiring board shown in
The multi-layer wiring board in accordance with the second embodiment has at least features described below:
(1) The multi-layer wiring board is provided with a motherboard 210 having a first surface, a first base material 221A with single-sided wiring circuit, which is bonded to the first surface, and has an outer shape that has been formed into a predetermined shape and a second base material 221B with single-sided wiring circuit, which is bonded to the surface of the first base material, and has an outer shape that has been formed into a predetermined shape, and in this arrangement, the first base material is provided with a first inner via hole 225 that electrically connects a wiring on the motherboard to a wiring on the first base material, and the second base material is provided with a second inner via hole 225 that electrically connects a wiring on the first base material to a wiring on the second base material, and when viewed from the direction of the normal line of the motherboard, the outer shape 229 of the second base material 221B bonded to the surface of the first base material is located inside the outer shape 229 of the first base material 221A bonded to the first surface of the wiring board.
(2) When viewed from the direction of the normal line of the motherboard, the outer shape 229 of the third base material 221C bonded to the surface of the second base material is located inside the outer shape 229 of the second base material 221B.
(3) A first base material peripheral edge line 229 that determines the peripheral edge of the rear surface of the first base material bonded to the first surface of the motherboard is located inside a motherboard print peripheral edge line 229 that determines the peripheral edge of the motherboard, without contacting the corresponding line.
Third Embodiment
The partial multi-layer wiring boards 320A, 320B, 320C and 320D are formed as follows: a plurality of single-sided circuit board for multi-layer wiring boards 330, which have outer shapes that have been formed into predetermined shapes that are smaller than the outer shape of the motherboard 310, are laminated on the surface and rear surface of the motherboard 310 by a batch process. In the present embodiment, each of the partial multi-layer wiring boards 320A, 320B, 320C and 320D has a two-layer structure.
Each of the single-sided circuit board for multi-layer wiring boards 330 has an insulating base material 331, a conductive pattern 332 formed on one surface of the insulating base material 331, a layering layer 333 bonded to the other surface of the insulating base material 331 and an interlayer conductive portion 334 prepared as an inner via hole formed in a manner so as to penetrate the insulating base material 331 and the layering layer 333.
The single-sided circuit board for multi-layer wiring board 330 may be prepared as either a rigid printed wiring board made from a material such as a phenol-based resin and an epoxy-based resin, or a flexible printed wiring board made from a material such as a polyester-based resin and a polyimide-based resin. Here, in the case when the insulating substrate 331 of the single-sided circuit board for multi-layer wiring board 330 has an interlayer layering property, the layering layer 333 may be omitted.
Among the single-sided circuit board for multi-layer wiring boards 330 of the partial multi-layer wiring boards 320A, 320B, 320C and 320D, the surface of the single-sided circuit board for multi-layer wiring board 330 performing as the outermost layer is coated with solder resist 335.
The single-sided circuit board for multi-layer wiring board 330 performing as the outermost layer of each of the partial multi-layer wiring boards 320A, 320B, 320C and 320D is provided with an electronic part 350 packaged thereon through a bump 351. Thus, it is possible to provide a double-sided multi-layer/double-sided packaging circuit substrate.
The motherboard 310 is prepared as a main single-sided circuit substrate having a conductive pattern 312 formed on one surface of an insulating base material 311. In he motherboard 310, at least one portion (two portions in this embodiment) of the insulating base material 311 is partially removed with the rear surface of the conductive pattern 312 being exposed at the removed portion 319 of the insulating base material 311. Further, on the other face side (rear face side) of the insulating se material 311, the single-sided circuit board for multi-layer wiring boards 330 of partial multi-layer wiring boards 320C and 320D are laminated in a manner so as to be conduction-connected to a rear-surface exposure portion 312B of the conductive pattern 312 to form the partial multi-layer wiring boards 320C and 320D.
Here the single-sided circuit board for multi layer wiring boards 330 of the partial multi-layer wiring boards 320A and 320B are laminated on one surface (surface) of the insulating base material 311 in a manner so as to be electrically connected to a surface exposure portion 312A of the conductive pattern 312 to form the partial multi-layer wiring boards 320A and 320B.
The motherboard 310 may also be prepared as either a rigid printed wiring board made from a material such as phenol-based resin and an epoxy-based resin, or a flexible printed wiring board made from a material such as a polyester-based resin and a polyimide-based resin.
The surface of the motherboard 310 is coated with a cover layer 318. Moreover, a gap portion between the cover layer 318 and the partial multi-layer wiring boards 320A and 320B is filled with solder resist 317 applied thereto.
With reference to FIGS. 22 to 25, a manufacturing method of circuits substrates constituting a multi-layer wiring board in accordance with the present embodiment described above will be described below.
Here, polyimide is selected as the insulating base material from the viewpoints of heat resistance and dielectric properties of the substrate, and other substrates such as a steel coat phenol substrate, a copper coat paper epoxy substrate, a steel coat paper polyester substrate, a copper coat glass epoxy substrate and a copper coat glass polyimide substrate, composed of a base material made from base material, such as glass cloth, glass mat and synthetic fibers, and a thermosetting resin, may be used. Moreover, with respect to a structure in which no base material is combined, a copper coat polyester substrate, a copper coat polyether imide substrate and a copper coat liquid crystal polymer substrate may be used.
First, in a conductive pattern forming process, etching resist is laminated on a copper foil 316 of the single-sided copper coat polyimide base material 360, and this is subjected to exposure to form a wiring pattern thereon, and then developed. Thereafter, the exposed copper is etched through a cupric chloride bath to form a conductive pattern 312. Subsequently, the etching resist is removed so that a single-sided circuit substrate 361, shown in
As shown in
Next, in an insulating base material removing process, as shown in FIG. 22D, etching resist 362 is laminated on both of the surfaces of the single-sided circuit substrate 361, and the copper foil side (surface side) is entirely subjected to exposure, and the polyimide side (rear surface side) is subjected to exposure to form an opening pattern, and then developed.
Thereafter, the insulating base material 311 made from polyimide is etched by using oxygen plasma or a strong alkali aqueous solution. Upon completion of the etching, the etching resist 362 is removed. Thus, as shown in
Additionally, the insulating base material removing process for forming the removed portion 319 in the insulating base material 311 may also be carried out by a laser process which applies a laser beam from the rear surface side of the insulating base material 311.
With reference to
The single-sided copper coat polyimide base material 370, which is the same as the single-sided copper coat polyimide base material 360 for use in the motherboard 310, is a single-sided copper coat lamination plate (CCL) having copper foil 336 placed as a conductor layer on only one of the surfaces of the insulating base material 331 made of a polyimide film.
Here, the insulating base material 311 of the motherboard 310 and the insulating base material 331 of the single-sided circuit board for multi-layer wiring board 330 are preferably made from the same material from the viewpoints of thermal and mechanical properties.
First, as shown in
Subsequently, as shown in
Next, as shown in
Subsequently, as shown in
Here, with respect to the printing/injecting process of the conductive paste, a print method using a metal mask, a print method using a masking film and an injecting method using a dispenser can be used.
Subsequently, the lamination base material 371 on which the silver paste has been printed is heated in an oven so that the silver paste is dried.
The lamination base material 371 is pressed by using a die to form an outer shape thereof that is smaller than the outer shape of the motherboard 310 as indicated by dot line C. Thus, as shown in
Next, referring to
With respect to the positioning processes, rather than adopting a pin-alignment method that requires a space used for forming a pin hole, a positioning process using image recognition is more preferably adopted.
Next, as shown in
Lastly, the conductive pattern 332, exposed so as to package an electronic part, is coated with noble metal 338 such as gold to form a multi-layer wiring board that allows double-sided packaging processes.
The above-mentioned circuit substrate has the following features and effects.
(1) By solving the problem that, when the single-sided wiring board is used as a motherboard, double-sided multi-layer forming processes and double-sided packaging processes are not available, the single-sided wiring board can be used as the motherboard 310, that is, the main single-sided circuit substrate. Therefore, different from the case using the double-sided circuit substrate, it is not necessary to remove most of the conductor layer on one surface upon formation of the conductive pattern, thereby making it possible to reduce wasteful use of materials and resources. Moreover, it is not necessary to provide complex manufacturing processes for forming through holes and the like.
(2) The single-sided wiring board is used as the motherboard 310. Therefore, in the case when the motherboard 310 is a flexible substrate, portions having no multi-layer structure are allowed to have a high bending property so that it is possible to provide a high-density double-sided partial multi-layer wiring board having a superior bending property.
(3) With respect to the partial multi-layer wiring board, that is, the in single-sided circuit board for multi-layer wiring board 330, those substrates that are formed to have outer shapes corresponding to the sizes of the partial multi-layer wiring portions are used. Therefore, in comparison with a case in which: those substrates corresponding to the partial multi-layer wiring portions are also prepared to have the same size as that of the motherboard 310, and upon forming the outer shape of the motherboard 310, each substrate is punched out to have the same outer shape as the motherboard 310, it is possible to reduce the quantity of materials for the multi-layer wiring board-use one-side circuit substrate 330, and consequently to cut wasteful use of materials.
Not limited to the above-mentioned double-sided lamination substrate, the circuit substrate of the present invention may have an arrangement in which as shown in
With reference to Figures, the following description will discuss a fourth embodiment of the present invention.
The relay board 410 is constituted by a base material with single-sided wiring circuit that is provided with a conductor layer (including a conductor land portion) 412 forming a wiring pattern, which is formed on one surface (upper surface 410A) of an insulating base material 411 that is compatibly used as an adhesive layer. With respect to the material for the insulating base material 411 compatibly used as the adhesive layer, thermosetting polyimide, thermoplastic polyimide, thermoplastic polyimide to which a thermosetting property is imparted, liquid crystal polymer, epoxy resin and the like can be used.
On the conductor layer surface (upper surface 410A) forming the wiring pattern of the insulating board 411, an insulating resin layer 413, which also performs as an adhesive layer, is formed. The insulating resin layer 413 and the insulating board 411 may be made of the same material.
With respect to the relay board 410, interlayer conductive portions 415 and 417 formed by via holes 414 and 416 are respectively formed in the insulating base material 411 and the insulating resin layer 413. The interlayer conductive portions 415 and 417 are constituted by the via holes 414 and 416 in which conductive paste is embedded and injected.
On the surface of the insulating base material 411 on the side opposite to the conductor layer surface, that is, the rear surface 410B, and the surface (upper surface 413A) of the insulating resin layer 413, wiring board for partial multi-layers 430 having outer shapes that have been preliminarily formed into a predetermined shape are laminated in conductive-association with the conductor layer 412 forming the wiring pattern of the relay board 410 through the interlayer conductive portion 415 or 417.
In the same manner as the relay board 410, the wiring board for partial multi-layer 430 is also constituted by a base material with single-sided wiring circuit that is provided with a conductor layer (including a conductor land portion) 432 forming a wiring pattern, which is formed on one surface of an insulating base material 431 that is compatibly used as an adhesive layer. With respect to the wiring board for partial multi-layer 430, an interlayer conductive portion 434 is formed in the insulating base material 431 through a via hole 433. The interlayer conductive portion 434 is also constituted by the via hole 433 in which conductive paste is embedded and injected.
With respect to the wiring board for partial multi-layer 430, on the upper surface 410A side of the relay board 410, that is, on the partial multi-layer portion 420A, a plurality of them are laminated with the conductor layer 432 forming a wiring pattern facing down, and on the rear-surface 410B side of the relay board 410, that is, on the partial multi-layer portion 420B, a plurality of them are laminated with the conductor layer 432 forming a wiring pattern facing up, thus, these layers are bonded by the insulating base material 411, the insulating resin layer 413 or the insulating base material 431, which serve as adhesive layers between layers. In other words, the wiring board for partial multi-layers 430 are laminated on the upper side and the lower side of the relay board 410 with the conductor layer 432 side thereof forming a wiring pattern facing the relay board 410 side.
On the surface 430A of the insulating base material 43 1 of the wiring board for partial multi-layer 430 that forms the outermost layer of each of the partial multi-layer portions 420A and 420B, a conductor layer 435 forming a wiring pattern and a component-packaging-use conductor land portion 436 are formed.
With the above-mentioned structure, even when a lamination material having a conductor layer such as copper foil formed on only one surface of the insulating base material 411 is used as a starting material, a partial multi-layer structure is prepared at desired portions on both of the surface and rear surface of the relay board 410, thereby allowing double-sided packaging processes. Moreover, by using the wiring board for partial multi-layer 430 having an outer shape that has been preliminarily formed into a predetermined shape, it becomes possible to eliminate the necessity of preparing excessive multi-layer portions, and consequently to cut the number of processes and the material costs.
With reference to
First, etching resist is laminated on the copper foil 451 of the single-sided copper coat polyimide base material 450, and this is subjected to exposure to form a wiring pattern thereon, and then developed. Thereafter, the exposed copper is etched through a cupric chloride bath to form a conductor layer (conductive pattern) 412. Subsequently, the etching resist is removed so that a substrate with single-sided circuit 452, shown in
Subsequently, as shown in
Subsequently, as shown in
With respect to the hole-forming processes, besides the laser processes, the via holes 414 and 416 may be formed by forming etching resist having a pattern on the insulating base material 411 and the insulating resin layer 413 and by etching the insulating base material 411 and the insulating resin layer 413.
Subsequently, as shown in
With respect to the relay board 410, since the conductive layer 412 forming the wiring pattern, except for the interlayer conductive portions 415 and 417, is coated with the insulating resin layer 413, and therefore it is possible to omit the process for placing the cover layer for protecting the conductor layer 412 forming the wiring pattern.
As shown in
Further, as shown in
Lastly, as shown in
The conductor layer 435 forming the wiring pattern on the outermost layer and the component-packaging-use conductor land portions 436 may also be formed by using a circuit-forming transfer tape 460 as shown in
As shown in
Thus, a multi-layer wiring board having the same properties as those of the aforementioned embodiments is provided. In this embodiment, the conductor layer 435 forming the wiring pattern on the outermost layer and the component-packaging-use conductor land portions 436 are pushed into the insulating base material 431 of the wiring board for partial multi-layer 430 through curing as shown in
As shown in
Thereafter, as shown in
The formation of the contact hole 473 is carried out by using an etching process in which only the insulating base material 471 is fused by etchant, with predetermined portions other than the contact-hole opening portions being protected by chemical resistant resist. Moreover, the contact holes 473 may be formed through a laser process using UV-YAG laser, carbon dioxide laser or the like.
In the present embodiment, since the conductor layer forming a wiring pattern on the surfaces of the partial multi-layer portions 420A and 420B is coated with the insulating base material 471, and therefore it is not necessary to separately prepare a cover layer for protecting the conductor layer forming the wiring pattern on the surfaces of the partial multi-layer portions 420A and 420B. Moreover, as shown in
Fourth Embodiment-Modified Embodiment
The relay board 4110 is comprised of a base material with single-sided wiring circuit that is provided with a conductor layer (including a conductor land portion) 4112 performing as a wiring pattern, which is formed on one surface (upper surface 4110A) of an insulating base material 4111 that is made from polyimide or the like. An interlayer bonding layer 4141 is formed on the other surface of the insulating base material 4111 so that the insulating layer is allowed to have a two-layer structure with the insulating base material 4111 and the interlayer bonding layer 4141. With respect to the material for the interlayer bonding layer 4141, thermosetting polyimide, thermoplastic polyimide, thermoplastic polyimide to which a thermosetting property is imparted, liquid crystal polymer, epoxy resin and the like can be used.
On the conductor layer surface (upper surface 4110A) forming the wiring pattern if the insulating board 4111, an insulating resin layer 4113, which also performs as an interlayer bonding layer, is formed. The insulating resin layer 4113 may be formed the same material as the material of the interlayer bonding layer 4141.
With respect to the relay board 4110, interlayer conductive portions 4115 and 4117 formed by via holes 4114 and 4116 are respectively formed in the insulating base material 4111, the interlayer bonding layer 4141 and the insulating resin layer 4113. The interlayer conductive portions 4115 and 4117 are constituted by the via holes 4114 and 4116 in which conductive paste is embedded and injected.
On the surface of the interlayer bonding layer 4141 on the side opposite to the insulating base material 4111, that is, the rear surface 4110B and the surface (upper surface 4113A) of the insulating resin layer 4113, wiring board for partial multi-layers 4130 having outer shapes that have been preliminarily formed into predetermined shapes are laminated in conductive-association with the conductor layer 4112 forming the wiring pattern of the relay board 4110 through the interlayer conductive portion 4115 or 4117.
In the same manner as the relay board 4110, the wiring board for partial multi-layer 4130 is also comprised of a base material with single-sided wiring circuit that is provided with a conductor layer (including a conductor land portion) 4132 forming a wiring pattern, which is formed on one surface of an insulating base material 4131. An adhesive layer 4142 is formed on the other surface of the insulating base material 4131. With respect to the wiring board for partial multi-layer 4130, an interlayer conductor portion 4134 is formed in the insulating base material 4131 and the adhesive layer 4142 through a via hole 4133. The interlayer conductive portion 4134 is also constituted by the via hole 4133 in which conductive paste is embedded and injected.
With respect to the wiring board for partial multi-layer 4130, on the upper surface 4113A side of the relay board 4110, that is, on the partial multi-layer portion 4120A, a plurality of them are laminated with the conductor layer 4132 forming a wiring pattern facing down, and on the rear-surface 4110B side of the relay board 4110, that is, on the partial Iti-1a er portion 4120B, a plurality of them are laminated with the conductor layer 4132 forming a wiring pattern facing up, thus, these layers are bonded by the adhesive layers 4141 and 4142 or the insulating resin layer 4113, which are located between layers. In other words, the wiring board for partial multi-layers 4130 are laminated on the upper side and the lower side of the relay board 4110 with the conductor layer 4132 side thereof forming a wiring pattern facing the relay board 4110 side.
On the surface 4130A of the adhesive layer 4142 of the wiring board for partial multi-layer 4130 that forms the outermost layer of each of the partial multi-layer portions 4120A and 4120B, a conductor layer 4135 forming a wiring pattern and a component-packaging-use conductor land portion 4136 are formed.
With the above-mentioned structure, even when a lamination material having a conductor layer such as copper foil formed on only one surface of the insulating base material 4111 is used as a starting material, a partial multi-layer structure is prepared at desired portions on both of the surface and rear surface of the relay board 4110, thereby allowing double-sided packaging processes. Moreover, by using the wiring board for partial multi-layer 4130 having an outer shape that has been preliminarily formed into a predetermined shape. It becomes possible to eliminate the necessity of preparing excessive multi-layer portions, and consequently to cut the number of processes and the material costs.
With reference to FIGS. 37 to 39, a manufacturing method for a multi-layer wiring board to be used for the above-mentioned modified embodiment of the present embodiment will be described below.
First, etching resist is laminated on the copper foil 4151 of the single-sided copper coat polyimide base material 4150, and this is subjected to exposure to form a wiring pattern thereon, and then developed. Thereafter, the exposed copper is etched through a cupric chloride bath to form a conductor layer (conductive pattern) 4112. Subsequently, the etching resist is removed so that a substrate with single-sided circuit 4152, shown in
As shown in
Subsequently, as shown in
Subsequently; as shown in
In this modified embodiment also, with respect to the relay board 4110, since the conductive layer 4112 forming the wiring pattern, except for the interlayer conductive portions 4115 and 4117, is coated with the insulating resin layer 4113. It is possible to omit the process for placing the cover layer for protecting the conductor layer 4112 forming the wiring pattern.
As shown in
Further, as shown in
Lastly, the surface and rear-surface outermost-layer-use copper foils 4137 are respectively etched so that a conductor layer 4135 forming a wiring pattern and component-packaging-use conductor land portions 4136 are formed. Thus, a multi-layer wiring board having partial multi-layer portions 4120A and 4120B is completed.
In this modified embodiment also, the conductor layer 4135 forming the wiring pattern on the outermost layer and the component-packaging-use conductor land portions 4136 may be formed by using a circuit-forming transfer tape that is the same as the circuit-forming transfer tape 460 shown in
In accordance with the present invention, at least one base material having a wiring circuit that has been preliminarily formed into a predetermined outer shape is bonded to a motherboard, and these are electrically connected to each other through at least an inner via hole. The outer shape of the base material having a wiring circuit is made smaller than the outer shape of the motherboard with the base material, having a wiring circuit having an island shape on the motherboard. Therefore, it becomes possible to provide a higher design freedom for wiring, and consequently to cut material costs and achieve a reduction in the substrate capacitance.
Moreover, in accordance with the present invention, at least one base material with single-sided wiring circuit that has been preliminarily formed into a predetermined outer shape is bonded to a motherboard, and these are electrically connected to each other at least one portion through an inner via hole. The outer shape of the base material with single-sided wiring circuit is made smaller than the outer shape of the motherboard with the base material, having a wiring circuit having an island shape on the motherboard. Therefore, it becomes possible to provide a higher design freedom for wiring, and consequently to cut material costs and achieve a reduction in the substrate capacitance.
Moreover, the base material with single-sided wiring circuit laminated on the motherboard is positioned so that an outer shape of a second base material bonded to the first base material is located inside the outer shape of the first base material on the motherboard side, and is allowed to have a pyramid shape, and therefore, upon bending the motherboard, stress imposed between the motherboard and the substrate with single-sided wiring circuit as well as between the laminated substrates with single-sided wiring circuit can be dispersed and alleviated. Therefore, it becomes possible to provide high anti-bending strength (peel strength), and consequently to achieve a good bending property that is a feature of the multi-layer flexible printed wiring board (FPC).
Moreover, in accordance with the present invention, at least one portion of the insulating base material of the main single-sided circuit substrate is partially removed, and the rear surface of a conductive pattern is exposed at the removed portion, and from the other side of the insulating base material of the main single-sided circuit substrate, an electronic part is assembled in a state in which it is conduction-connected to the rear-face exposed portion of the conductive pattern, and/or a single-sided circuit board for multi-layer wiring board having an interlayer conductive portion and a conductive pattern formed on one face of an insulating base material is laminated in a state in which it is conduction-connected to the rear-face exposed-portion of the conductive pattern. Moreover, on the other face of the insulating base material of the main single-sided circuit substrate also, an electronic part is assembled and/or a single-sided circuit board for multi-layer wiring board is laminated so that it is possible to provide a circuit substrate that allows double-sided packaging processes.
Furthermore, in accordance with the present invention, an insulating resin layer, which also serves as an adhesive layer, is formed on the conductor layer surface side of a relay board, and an interlayer conductive portion derived from a conductive substance injected into a via hole formed in an insulating base material and an interlayer conductive portion derived from a conductive substance injected into a via hole formed in the insulating resin layer are prepared; therefore, even when a lamination material having a conductive layer such as copper foil only on one surface of the insulating base material is used as a starting material, it is possible to partially prepare a multi-layer structure at a desired portion on both of the surface and rear surface of the relay board, and consequently to allow double-sided packaging processes.
Claims
1. A multi-layer wiring board comprising:
- a motherboard; and
- at least one base material having a wiring circuit which is formed into a predetermined outer shape and is laminated with the motherboard,
- wherein the motherboard and the base material having a wiring circuit are electrically connected to each other through an inner via hole.
2. The multi-layer wiring board according to claim 1, wherein the outer shape of the base material having a wiring circuit is smaller than the outer shape of the motherboard, and wherein the base material having a wiring circuit is arranged on the motherboard to form an island shape.
3. The multi-layer wiring board according to claim 1 or claim 2, wherein a plurality of the base materials having a wiring circuit which is formed into a predetermined outer shape are laminated on the motherboard.
4. The multi-layer wiring board according to any one of claims 1 or 2, wherein the base material having a wiring circuit comprises a base material with single-sided wiring circuit having an insulating layer and a wiring circuit formed on one surface of the insulating layer.
5. The multi-layer wiring board according to any one of claims 1 or 2, wherein an insulating layer of the motherboard is made of a flexible resin.
6. The multi-layer wiring board according to any one of claims 1 or 2, wherein the insulating layer of the base material having a wiring circuit is made of a flexible resin
7. The multi-layer wiring board according to any one of claims 1 or 2, wherein the insulating layer of the motherboard and the insulating layer of the base material having a wiring circuit are made of the same material.
8. The multi-layer wiring board according to any one of claims 1 or 2, wherein a cover layer for coating the motherboard and the base material having a wiring circuit is formed.
9. The multi-layer wiring board according to any one of claims 1 or 2, wherein a cover layer having an opening is formed on the motherboard, and the base material having a wiring circuit is positioned in the opening.
10. The multi-layer wiring board according to claim 9, wherein the wiring circuit of the motherboard is exposed in a gap which is defined by the opening of the cover layer and the base material having a wiring circuit, and wherein the wiring circuit of the motherboard is coated with noble-metal.
11. The multi-layer wiring board according to claim 9, wherein a second cover layer is formed so that coats the surface of the wiring board of the motherboard being exposed in a gap which is defined by the opening of the cover layer and the base material having a wiring circuit.
12. The multi-layer wiring board according to any one of claims 1 or 2, wherein, among the base materials having a wiring circuit accordingly, the insulating layer of the base material having a wiring circuit that contacts the motherboard is also perform as the cover layer that covers the wiring circuit of the motherboard.
13. The multi-layer wiring board according to any one of claims 1 or 2, wherein the inner via hole in the base material having a wiring circuit is filled with conductive paste for electrically connect different layers one another.
14. The multi-layer wiring board according to claim 13, wherein a small hall communicating with the inner via hole is pierced in a conductor layer of the base material having a wiring circuit.
15. A method for manufacturing a multi-layer wiring board, comprising the step of:
- laminating a base material having a wiring circuit which is formed into a predetermined outer shape with at least one of a surface and a rear surface of a motherboard.
16. A method for manufacturing a multi-layer wiring board, comprising the steps of:
- forming a wiring circuit on at least one of a surface and a rear surface of the motherboard;
- making a via hole; and
- laminating a base material having a wiring circuit which is formed into a predetermined outer shape.
17. The method for manufacturing a multi-layer wiring board according to claim 15 or claim 16, wherein an outer shape of the base material having a wiring circuit is smaller than the outer shape of the motherboard.
18. The method for manufacturing a multi-layer wiring board of any one of claims 15 or 16 further comprising the step of:
- forming a cover layer having an opening for positioning the base material having a wiring circuit prior to the operation of laminating the base material having a wiring circuit with the motherboard.
19. The method for manufacturing a multi-layer wiring board according to any one of claims 15 or 16 further comprising the step of:
- forming a cover layer for coating the motherboard and the base material having a wiring circuit after the operation of laminating the base material having a wiring circuit with the motherboard.
20. A multi-layer wiring board comprising:
- a motherboard; and
- at least two base materials with single-sided wiring circuit, which are laminated with the motherboard,
- wherein the motherboard wiring board and the base material with single-sided wiring circuit are electrically connected to each other through an inner via hole, and the at least two laminated base materials are positioned so that the contour of one base material being laminated with the other base material is positioned inside the contour of the other base material being laminated with the motherboard.
21. The multi-layer wiring board according to claim 20, wherein the contour of the base material with single-sided wiring circuit is smaller than the contour of the motherboard circumference of the base material with single-sided wiring circuit is positioned inside circumference of the motherboard and wherein the base material with single-sided wiring circuit being formed into an island shape on the motherboard viewed from the laminating direction of the base materials.
22. The multi-layer wiring board according to claim 20 or claim 21, wherein the motherboard comprises an insulating layer made of a flexible resin.
23. The multi-layer wiring board according to any one of claims 20 or 21, wherein the base material with single-sided wiring circuit comprises an insulating layer made of a flexible resin.
24. The multi-layer wiring board according to any one of claims 20 or 21, wherein the insulating layer of the motherboard and the insulating layer of the base material with single-sided wiring circuit are made of the same material.
25. The multi-layer wiring board according to any one of claims 20 or 21, wherein a cover layer for coating the motherboard is formed.
26. The multi-layer wiring board according to any one of claims 20 or 21, wherein the inner via hole of the base material with single-sided wiring circuit is filled with conductive paste to electrically connect different layers one another.
27. A method for manufacturing a multi-layer wiring board, comprising the step of:
- laminating a base material with single-sided wiring circuit which is formed into a predetermined outer shape to at least one of the surface and rear surface of the motherboard.
28. A method for manufacturing a multi-layer wiring board comprising the steps of:
- preparing a resin plate to be used for a base material with single-sided wiring circuit;
- forming a circuit portion on one surface of the resin plate;
- making a via hole that penetrates the resin plate from the one surface to the other surface to reach at least one portion of the circuit portion formed on the one surface of resin plate;
- injecting conductive paste into the via hole;
- provisionally curing the conductive paste;
- dividing the base material with single-sided wiring circuit being formed by previous steps into a plurality of base materials with single-sided wiring circuits;
- positioning the base materials with single-sided wiring circuits on the motherboard to be placed thereon; and
- laminating the base materials with single-sided wiring circuits and the motherboard through a colaminating process while heating the base materials and the motherboard so that a main curing process on the conductive paste is performed.
29. A multi-layer wiring board comprising:
- a main single-sided circuit board which is comprised of a insulating base material including a conductive pattern on one face of the insulating base material,
- wherein at least one portion of the insulating base material is partially removed so that the rear face of the conductive pattern is exposed at the removed portion,
- and wherein at least one of an electric part and a single-sided circuit board for multi-layer wiring board having an interlayer conductive portion and a conductive pattern formed on one face of an insulating layer is electrically connected with a portion of the conductive pattern being exposed from the rear side of the insulating base material.
30. The multi-layer wiring board according to claim 29, wherein an electronic part is electrically connected with the conductive pattern of the main single-sided circuit from the one side of the main single-sided circuit board and a single-sided circuit board for multi-layer wiring board which is comprised of an interlayer conductive portion and an insulating base material including a conductive pattern formed on one face of the insulating base material is laminated so that the conductive pattern of the single-sided circuit board for multi-layer wiring board is electrically connect with the conductive pattern of the main single-sided circuit board.
31. The circuit substrate according to claim 29 or 30, wherein the main single-sided circuit board comprises a flexible wiring board.
32. The multi-layer wiring board according to any one of claims 29 or 30, wherein the main single-sided circuit board further comprises a motherboard, and the contour of the single-sided circuit board for multi-layer wiring board is smaller than the contour of the motherboard, and wherein the single-sided circuit board for multi-layer wiring board is arranged to form an island shape on the motherboard.
33. A method for manufacturing a multi-layer wiring board, comprising the steps of:
- forming a conductive pattern on a conductor layer being formed on one surface of an insulating base material of a laminated board including conductor layer formed on one surface which is processed as a starting material of a main single-sided circuit board;
- removing a portion of the insulating base material of the main single-sided circuit board so that a rear surface of the conductive pattern is exposed from the removed portion of the insulating base material;
- electrically connecting the conductive pattern being exposed in the removed portion with at least one of a electrical part from the rear side of the insulating base material of the main single-sided circuit board and a conductive pattern formed on an insulating layer of a single-sided circuit board for multi-layer wiring board having an interlayer connecting portion; and
- electrically connecting at least one of the conductive pattern on the one side of the main single-sided circuit board with a electrical part from the one side of the insulating base material of the main single-sided circuit board and the conductive pattern being exposed in the removed portion with a conductive pattern formed on an insulating layer of a single-sided circuit board for multi-layer board having an interlayer connecting portion.
34. The method for manufacturing a multi-layer wiring board according to claim 33, wherein removing process of the insulating base material of the main single-sided circuit board comprises an etching process or a laser process.
35. The method for manufacturing a multi-layer wiring board according to claim 33 or claim 34, wherein electrically connecting processes is carried out through a colaminating process.
36. A multi-layer wiring board comprising:
- a relay board which is comprised of an adhesive insulating base material and a base material with single-sided wiring circuit having a conductor layer on one surface of the insulating base material;
- and a wiring board for partial multi-layer being laminated on a desired area of the relay board, wherein
- the relay board further comprises an insulating resin layer formed on the conductor layer surface side, an interlayer conductive portion being comprised of a via hole which is filled with injected conductive substance and formed in the adhesive insulating base material and an interlayer conductive portion being comprised of a via hole which is filled with injected conductive substance and formed in the insulating resin layer,
- and wherein the wiring board for partial multi-layers are laminated on respective desired areas on the opposite surface of the conductive layer of the adhesive insulating base material and the surface of the insulating resin layer so that the wiring board for partial multi-layers are electrically connected with the relay board accordingly.
37. A multi-layer wiring board comprising:
- a relay board which is comprised of an insulating base material having a conductor layer, an insulating resin layer coating the conductor layer and an interlayer bonding layer; and
- a wiring board for partial multi-layer being laminated on a specific area of the relay board, wherein
- the relay board further comprises an interlayer conductive portion being comprised of a via hole which is filled with injected conductive substance and formed in the interlayer bonding layer and the insulating base material and wherein the wiring boards for partial multi-layer are laminated on respective desired areas on the surface of the interlayer bonding layer and the surface of the insulating resin layer so that the wiring board for partial multi-layers are electrically connected with the relay board accordingly.
38. The multi-layer wiring board according to claim 36 or claim 37, wherein the insulating resin layer of the relay board also performs as an interlayer bonding layer.
39. The multi-layer wiring board according to any one of claims 36 or 37, wherein the wiring board for partial multi-layer further comprises a base material with single-sided wiring circuit that includes an adhesive insulating base material and a conductor layer being formed on the adhesive insulating base material,
- and wherein the wiring board for partial multi-layer is laminated with the relay board and land portions formed on the surfaces of the adhesive insulating base material of the both outer surface side of the wiring board for partial multi-layers portion being laminated on both sides of the relay board are electrically connected with a electrical art.
40. The multi-layer wiring board according to an one of claims 36 or 37, wherein the wiring board for partial multi-layer further comprises a base material with single-sided wiring circuit that includes an insulating base material an interlayer bonding layer coating the insulating base material and a conductor layer being formed on the interlayer bonding layer,
- and wherein the wiring board for partial multi-layer is laminated with the relay board, and land portions formed on the surfaces of the interlayer bonding layers of the both outer surface side of the wiring board for partial multi-layers portion being laminated on both sides of the relay board are electrically connected with a electrical part.
41. The multi-layer wiring board according to any one of claims 36 or 37, wherein the wiring board for partial multi-layer is comprised of a base material with single-sided wiring circuit that has a conductor layer on an adhesive insulating base material,
- wherein the wiring board for partial multi-layer is laminated with the relay board under condition that the conductor layer surface of the wiring board for partial multi-layer being faced to the relay board,
- and wherein contact holes for electrically connecting with an electrical part are formed in an adhesive insulating base material so that the contact portions are communicated with land portions being formed on conductor layers of the wiring board for partial multi-layers of both sides of the outermost partial multi-layer portions of the relay board.
42. The multi-layer wiring board according to any one of claims 36 or 37, wherein
- the wiring board for partial multi-layer is comprised of a base material with single-sided wiring circuit that includes an insulating base material an interlayer bonding layer coating the insulating base material and a conductor layer formed on the insulating base material,
- wherein the wiring board for partial multi-layer is laminated with the relay board under condition that the conductor layer surface of the wiring board for partial multi-layer being faced to the relay board,
- and wherein contact holes for electrically connecting with an electrical art are formed in an insulating base material and an interlayer bonding layer so that the contact portions are communicated with land portions being formed on conductor layers of the wiring board for partial multi-layers of both sides of the outermost partial multi-layer portions of the relay board.
43. A method for manufacturing a multi-layer wiring board comprising the steps of:
- forming a circuit on a conductor layer formed on only one surface of an adhesive insulating base material of a wiring circuit board base material being processed as a starting material for a relay board;
- forming an insulating resin layer coating the conductor layer of the adhesive insulating base material;
- making via holes in the adhesive insulating base material and the insulating resin layer of the relay board so that interlayer conductive portions being filled with a conductive substance injected into the via holes are formed in the insulating resin layer and the adhesive insulating base material; and
- laminating a wiring board for partial multi-layer being preliminarily formed into a predetermined outer shape at least on one of a specific area on the surface of the adhesive insulating base material and a specific area on the surface of the insulating resin layer so that the wiring board for partial multi-layer is electrically connected with the relay board.
44. A method for manufacturing a multi-layer wiring board comprising the steps of:
- forming a circuit on a conductor layer formed on one surface of an insulating base material of a wiring circuit board base material being processed as a starting material for a relay board;
- forming an interlayer bonding layer on the other surface of the insulating base material of the wiring circuit board base material;
- forming an insulating resin layer coating the conductor layer of the insulating base material;
- making via holes in the insulating base material the insulating resin layer, and the interlayer bonding layer so that interlayer conductive portions being filled with a conductive substance injected into the via holes are formed in the insulating resin layer, the insulating base material and the interlayer bonding layer; and
- laminating a wiring board for partial multi-layer being preliminarily formed into a predetermined outer shape at least on one of a specific area on the surface of the insulating resin layer and a specific area on the surface of the interlayer bonding layer so that the wiring board for partial multi-layer is electrically connected with the relay board.
45. A forming-use member in which a plurality of the base materials with wiring circuits to be used for the multi-layer wiring board disclosed in claim 1 are formed.
Type: Application
Filed: Dec 19, 2003
Publication Date: Aug 17, 2006
Inventors: Shoji Ito (Chiba), Ryoichi Kishihara (Chiba), Osamu Nakao (Chiba), Hiroki Hashiba (Chiba), Masahiro Okamoto (Chiba)
Application Number: 10/542,649
International Classification: H05K 1/11 (20060101); H05K 1/09 (20060101); H05K 1/03 (20060101);