JP4006971B2 - Circuit board manufacturing method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a circuit board manufacturing method using a flexible film having a highly accurate circuit pattern and excellent productivity.
[0002]
[Prior art]
As electronics products become lighter and smaller, printed circuit board patterning needs to be highly accurate. Among them, the flexible film substrate can be bent, so that three-dimensional wiring can be performed, and the demand is increasing because it is suitable for downsizing of electronic products. TAB (Tape Automated Bonding) technology used for IC connection to a liquid crystal display panel can obtain the finest pattern that is the best as a resin substrate by processing a relatively narrow long polyimide film substrate. The progress of computerization is approaching the limit. For miniaturization, there are an index represented by a line width and a space width between lines, and an index represented by a position of a pattern on a substrate. The latter index, the so-called cumulative accuracy, is related to the alignment of the electrode pad and circuit board pattern when connecting a circuit board and an electronic component such as an IC, and corresponds to the accuracy required as the number of pins of IC increases. It is getting harder to do.
[0003]
[Problems to be solved by the invention]
In terms of the cumulative accuracy, the flexible film substrate processing is becoming difficult to improve. Circuit board processing includes heat treatment processes such as drying and curing, and wet processes such as etching and development, and the flexible film repeatedly expands and contracts. The hysteresis at this time causes displacement of the circuit pattern on the substrate. In addition, when there are a plurality of processes that require alignment, if there is expansion or contraction between these processes, positional deviation occurs between the formed patterns. Deformation due to expansion and contraction of the flexible film has an even greater effect in the case of an FPC (flexible printed circuit board) in which processing is performed with a relatively large substrate size. Further, the positional displacement is caused by an external force such as pulling or twisting, and special attention is required when a thin substrate is used to increase flexibility.
[0004]
An object of the present invention is to solve the above problems and to provide a high-definition flexible film circuit board provided with circuit patterns on both sides.
[0005]
[Means for Solving the Problems]
  In order to achieve the above object of the present invention, the present invention comprises the following constitution. That is, a metal layer having a thickness of 5 μm or more is formed on at least one surface of the flexible film, and thenOne of the surfaces on which the metal layer is formedAfter patterning the metal layer, the reinforcing plate is bonded to one surface of the patterned metal layer forming surface via a peelable organic material layer, and then a circuit pattern is formed on the surface where the reinforcing plate is not bonded. Then, the flexible film is peeled off from the reinforcing plate.
[0006]
DETAILED DESCRIPTION OF THE INVENTION
In a typical embodiment of the present invention, a metal layer having a thickness of 5 μm or more is formed on at least one surface of a flexible film, and then a reinforcing plate can be peeled off on one surface of the exposed metal layer. Then, after forming a circuit pattern on the surface where the reinforcing plate is not bonded, the flexible film is peeled off from the reinforcing plate.
[0007]
In the present invention, the flexible film is a plastic film, and it is important that the flexible film has a heat resistance sufficient to withstand a thermal process in a circuit pattern manufacturing process and electronic component mounting, such as polycarbonate, polyether sulfide, Films such as polyethylene terephthalate, polyethylene naphthalate, polyphenylene sulfide, polyimide, polyamide, and liquid crystal polymer can be employed. Among these, a polyimide film is preferably used because it is excellent in heat resistance and chemical resistance. In addition, a liquid crystal polymer is preferably used because it has excellent electrical characteristics such as low dielectric loss. It is also possible to employ a flexible glass fiber reinforced resin plate.
[0008]
Examples of the resin for the glass fiber reinforced resin plate include polyphenylene sulfide, polyphenylene ether, maleimide, polyamide, and polyimide.
[0009]
The thickness of the flexible film is preferably thinner in order to reduce the weight and size of electronic devices, or to form fine via holes. On the other hand, in order to ensure mechanical strength and maintain flatness. From the viewpoint that a thicker one is preferable, a range of 12.5 μm to 125 μm is preferable.
[0010]
As the substrate used as the reinforcing plate in the present invention, inorganic glass such as soda lime glass, borosilicate glass, alumino borosilicate glass, quartz glass, metal such as Invar alloy, titanium, glass fiber reinforced resin plate, and the like can be adopted. Here, the glass fiber reinforced resin plate used as the reinforcing plate is thicker and harder than the glass fiber reinforced resin plate used as the flexible film. Both are preferable because of their low linear expansion coefficient and hygroscopic expansion coefficient, but they are excellent in heat resistance and chemical resistance in the circuit pattern manufacturing process, and are easy to obtain inexpensively because of their large area and high surface smoothness. Inorganic glasses are preferred in that they are difficult to plastically deform or are less likely to generate particles upon contact. Among these, alkali-free glass typified by aluminoborosilicate glass is particularly preferable because it has a high elastic modulus and a small thermal expansion coefficient.
[0011]
In addition, when the peelable organic layer is of a type whose adhesive strength and adhesive strength are reduced by ultraviolet irradiation, it is preferably a substrate through which ultraviolet rays pass. As an example of the production method of the present invention, the surface (first surface) of the metal layer formed on the flexible film is bonded to the first reinforcing plate via the peelable organic layer, After the circuit pattern is formed on the second surface on the opposite side, the second reinforcing plate is bonded to the circuit pattern on the second surface via a peelable organic layer, and then the first reinforcing plate is attached. There is a method of peeling, forming a circuit pattern based on the metal layer already formed on the first surface of the flexible film, and peeling the second reinforcing plate. According to this method, a circuit pattern with particularly high accuracy can be produced on both sides of the flexible film. In this way, it takes a configuration in which a reinforcing plate is bonded to both sides of the film during the process, and when it is desired to peel only the reinforcing plate on one side, the peelable organic material layer is a type whose adhesive force and adhesive strength are reduced by UV irradiation, And it is preferable that a reinforcement board is a board | substrate which lets an ultraviolet-ray pass.
[0012]
When a metal or glass fiber reinforced resin is used for the reinforcing plate, it can be manufactured in a long continuum, but the circuit board manufacturing method of the present invention should be a single wafer type because it is easy to ensure the accumulative accuracy. Is preferred. A sheet means a state where it is handled as an individual sheet, not a long continuous body.
[0013]
If the glass substrate used for the reinforcing plate has a small Young's modulus or a small thickness, the expansion / contraction force of the flexible film causes large warping and twisting, and the glass substrate breaks when vacuum-adsorbed on a flat stage. Sometimes. In addition, the flexible film is deformed by vacuum adsorption / desorption, and it tends to be difficult to ensure positional accuracy. On the other hand, when the glass substrate is thick, the flatness may deteriorate due to uneven thickness, and the exposure accuracy tends to deteriorate. In addition, a handling load by a robot or the like is increased, and it is difficult to quickly handle the machine, resulting in a decrease in productivity, and a transportation cost tends to increase.
[0014]
From this point, the Young's modulus (kg / mm of the glass substrate which is the sheet reinforcing plate)²) And the cube of thickness (mm) is preferably in the range of 850 kg · mm to 860000 kg · mm, more preferably 1500 kg · mm to 190,000 kg · mm, and more preferably 2400 kg · mm to 110,000 kg · mm. The range of is most preferable.
[0015]
When using a metal substrate for the reinforcing plate, if the Young's modulus of the metal substrate is small, or if the thickness is small, warping and twisting will increase due to the expansion / contraction force of the flexible film, and it will be impossible to vacuum-adsorb on a flat stage. Securing position accuracy becomes difficult due to the warp and twist of the metal substrate and the deformation of the flexible film. Also, if there is a fold, it becomes a defective product at that time. On the other hand, when the metal substrate is thick, the flatness may be deteriorated due to uneven thickness, and the exposure accuracy is deteriorated. In addition, the load on handling by a robot or the like becomes large, making it difficult to handle quickly, which causes a decrease in productivity, and also increases the transportation cost.
[0016]
From this point, the Young's modulus (kg / mm of the metal substrate which is the sheet reinforcing plate)²) And the cube of the thickness (mm) is preferably in the range of 2 kg · mm to 162560 kg · mm. Young's modulus of metal substrate (kg / mm²) And the cube of thickness (mm) is more preferably 10 kg · mm to 30000 kg · mm, and most preferably 15 kg · mm to 20500 kg · mm.
[0017]
The peelable organic layer used in the present invention is composed of an adhesive or a pressure-sensitive adhesive, and is capable of peeling the flexible film after being processed by attaching the flexible film to the reinforcing plate via the organic layer. If it does not specifically limit. Examples of such an adhesive or pressure-sensitive adhesive include a pressure-sensitive adhesive called an acrylic or urethane-based re-peeling pressure-sensitive adhesive. Adhesive strength in the region called weak to medium adhesive is preferable in order to have sufficient adhesive force during flexible film processing, and can be easily peeled off during peeling and does not cause distortion in the flexible film substrate. .
[0018]
Although the silicone resin film is sometimes used as a release agent, those having tackiness can be used as a peelable organic layer in the present invention. In addition, it is also possible to use a tacky epoxy resin film as a peelable organic layer.
[0019]
When expressing a preferable adhesive force by a numerical value, a 180 ° peel strength when a base material is a polyester film and an adhesive tape in which an adhesive is laminated to a thickness of 25 μm is attached to a stainless steel plate and peeled is 1 g / 25 mm to 500 g / It is in the range of 25 mm. In particular, a range of 2 g / 25 mm to 200 g / 25 mm called weak adhesion is particularly preferable.
[0020]
In addition, those in which adhesive strength and adhesive strength are reduced in a low temperature region, those in which adhesive strength and adhesive strength are reduced by ultraviolet irradiation, and those in which adhesive strength and adhesive strength are reduced by heat treatment are also preferably used. Among these, those caused by ultraviolet irradiation are preferable because of large changes in adhesive strength and adhesive strength. An example of a material whose adhesive strength and adhesive strength are reduced by ultraviolet irradiation is a two-component cross-linking acrylic pressure-sensitive adhesive. Moreover, as an example of what adhesive force and adhesive force reduce in a low temperature area | region, the acrylic adhesive which reversibly changes between a crystalline state and an amorphous state is mentioned.
[0021]
In the present invention, a metal layer having a thickness of 5 μm or more is formed on at least one surface of the flexible film prior to bonding to the reinforcing plate, and the metal layer forming surface side is bonded to the reinforcing plate. This is very important. In the present invention, the dimensional accuracy is secured by fixing the flexible film to the reinforcing plate. Further, by forming a metal layer having a thickness of 5 μm or more on at least one surface of the flexible film. The deformation of the flexible film due to the tension when the flexible film is bonded to the reinforcing plate can be suppressed. It also helps to suppress hygroscopic expansion and drying shrinkage of the flexible film after being fixed to the reinforcing plate. The thickness of the metal layer is more preferably 8 μm or more, and most preferably 10 μm or more. On the other hand, if the metal layer is too thick, it becomes difficult to form fine wiring, and the flexible film may be deformed due to an increase in internal stress of the metal layer or internal stress of the adhesive layer for bonding the metal foil. 18 μm or less is preferable.
[0022]
The metal layer formed prior to the attachment with the reinforcing plate can be formed by attaching a metal foil such as a copper foil with an adhesive layer, or by sputtering, plating, or a combination thereof. . Alternatively, a flexible film with a metal layer can be made by applying, drying, and curing a raw material resin of a flexible film or a precursor thereof on a metal foil such as copper, and this can be used.
[0023]
  The metal layer is, SupplementForm a wiring circuit by panning before bonding to a strong boardTo do.Placed on the reinforcing plate after wiring circuit formationIfThe area of the metal layer remaining as the wiring and dummy pattern is preferably 50% or more. Alternatively, the wiring circuit may be directly formed by a full additive method without forming a solid metal layer, or the wiring circuit may be formed by a semi-additive method using a thin metal layer as a base layer. Also in this case, the area of the metal layer that is the wiring and the dummy pattern is preferably 50% or more in order to suppress deformation of the flexible film. More preferably, the area of the metal layer is 60% or more.
[0024]
  When the wiring circuit is formed before being attached to the reinforcing plateIfSimultaneously with the pattern formation, it is preferable to form an alignment mark with the circuit pattern formed on the other surface. In order to make use of the high definition of the high definition pattern formed on the surface opposite to the bonding surface, it is very effective to provide alignment by providing alignment marks. The alignment mark may be read through a transparent reinforcing plate or may be read through a flexible film. If a metal layer is formed on the side opposite to the bonding surface of the flexible film, Reading from the reinforcing plate side is preferable because reading is possible regardless of the layer pattern. This alignment mark can also be used for alignment when the flexible film is bonded to the reinforcing plate. The shape of the alignment mark is not particularly limited, and a shape generally used in an exposure machine or the like can be suitably employed.
[0025]
  Since the circuit pattern formed on the surface opposite to the affixing surface of the flexible film after being affixed to the reinforcing plate can prevent deformation of the flexible film that occurs during processing by the reinforcing plate and the metal layer, A highly accurate pattern can be formed. oneDirectionThe pattern formed on the surface to be attached to the strong board mainly serves as the input / output terminals to the printed wiring board and the surrounding wiring, power supply and ground potential wiring. There is a case where high definition as the pattern formed on the surface opposite to the attachment surface is not required. According to the present invention, it is easy to provide such a double-sided wiring in which a particularly fine pattern is formed on one side. Advantages of using double-sided wiring include crossover through through-holes, increasing the degree of freedom in wiring design, and LSI that operates at high speed by propagating the ground potential to the vicinity of the required location with thick wiring In addition, the power supply potential can be propagated to the vicinity of the necessary location with thick wiring, preventing potential drop even at high-speed switching, stabilizing the LSI operation, and blocking external noise as an electromagnetic wave shield. It becomes very important as the LSI speeds up and the number of pins increases due to the increase in functionality.
[0026]
Furthermore, in the present invention, it is possible to use a reinforcing plate when processing both sides of the flexible film, and to form a pattern with particularly high precision on both sides. For example, the first reinforcing plate and the second surface of the flexible film are bonded to each other via a peelable organic layer, and a circuit pattern is formed on the first surface of the flexible film. After the first surface and the second reinforcing plate are bonded together through a peelable organic layer, the flexible film is peeled off from the first reinforcing plate, and then the second film of the flexible film is peeled off. A method of peeling the flexible film from the second reinforcing plate after forming a circuit pattern on the surface is mentioned, and high-precision circuit pattern processing can be realized on both surfaces.
[0027]
An example of the method for producing a circuit board of the present invention will be described below, but the present invention is not limited to this.
[0028]
A weak adhesive re-peeling agent is applied to an aluminoborosilicate glass having a thickness of 0.7 mm using a spin coater, blade coater, roll coater, bar coater, die coater, screen printing or the like. Use of a die coater is preferable in order to uniformly apply to a single-wafer substrate sent intermittently. After the re-release agent is applied, the re-release agent layer having a thickness of 20 μm is obtained by drying by heat drying or vacuum drying. An air barrier film composed of a release film in which a silicone resin layer is provided on a polyester film is attached to the applied re-release agent layer and aged for one week. Instead of laminating the air blocking film, it can be stored in a nitrogen atmosphere or in a vacuum. It is also possible to apply a weak adhesive re-peeling agent to a long film substrate, transfer it to a single wafer substrate after drying.
[0029]
A polyimide film having a thickness of 25 μm is prepared, and a metal layer is formed on one side. As a method for forming a metal layer on one surface of the polyimide film, a metal foil such as a copper foil can be attached with an adhesive layer, and sputtering, plating, or a combination thereof can be employed. At this time, it is important to form the metal layer with a thickness of 5 μm or more.
[0030]
  In this way, when a solid metal layer is formed on the polyimide film, bonding to a glass substrateBeforeA circuit pattern can be formed by a subtractive method using a photoresist and an etching solution. The subtractive method can be suitably employed in that the manufacturing process is short and the cost is low.
[0031]
When the metal layer is not previously provided on the bonding surface of the polyimide film, the metal layer can be formed by a full additive method or a semi-additive method. At this time, circuit wiringAnd dummy patternThe area of the remaining metal layer is preferably 50% or more, and more preferably 60% or more.
[0032]
The full additive process is the following process. The surface on which the metal layer is to be formed is treated with a catalyst such as palladium, nickel or chromium and dried. The catalyst referred to here does not act as a nucleus for plating growth as it is, but it becomes a nucleus for plating growth by activation treatment. Next, the photoresist is applied by a spin coater, blade coater, roll coater, bar coater, die coater, screen printing or the like and dried. The photoresist is exposed and developed through a photomask having a predetermined pattern to form a resist layer in a portion where a plating film is unnecessary. Then, after activation treatment as necessary, the polyimide film is immersed in an electroless plating solution composed of a combination of copper sulfate and formaldehyde to form a copper plating film having a thickness of 2 μm to 20 μm. Get the circuit pattern.
[0033]
The semi-additive process is the following process. On the surface on which the metal layer is to be formed, chromium, nickel, copper, or an alloy thereof is sputtered to form an underlayer. The thickness of the underlayer is in the range of 1 nm to 1000 nm. Laminating a copper sputtered film on the underlayer further from 50 nm to 3000 nm is effective in improving the adhesion of the metal layer and preventing pinhole defects. Prior to the formation of the underlayer, plasma treatment, reverse sputtering treatment, primer layer application, and adhesive layer application are suitably performed on the polyimide film surface in order to improve adhesion. Among them, the application of an adhesive layer such as epoxy resin, acrylic resin, polyamide resin, polyimide resin, and NBR is preferable because it has a great effect of improving the adhesive force. These treatments and application may be performed before the glass substrate is pasted, or may be performed after the glass substrate is pasted. However, with respect to the surface to be initially attached to the reinforcing plate, these treatments and coatings are performed before the metal layer formation prior to the step of attaching to the reinforcing plate. It is preferable that continuous treatment with a roll-to-roll process is performed on a long polyimide film before attaching the glass substrate in order to improve productivity. A photoresist is applied onto the underlayer thus formed by a spin coater, blade coater, roll coater, die coater, screen printing or the like and dried. The photoresist is exposed and developed through a photomask having a predetermined pattern to form a resist layer in a portion where a plating film is unnecessary. Next, electrolytic plating is performed using the underlying layer as an electrode. As the electrolytic plating solution, a copper sulfate plating solution, a copper cyanide plating solution, a copper pyrophosphate plating solution, or the like is used. After forming a copper plating film having a thickness of 2 μm to 20 μm, the photoresist is peeled off, and then the underlying layer is removed by a light etching to obtain a circuit pattern.
[0034]
The air blocking film on the glass substrate is peeled off, and the polyimide film is attached to the glass substrate with the surface on which the circuit pattern is formed as the bonding surface. In pasting, the polyimide film may be pasted in a cut sheet having a predetermined size, or pasted and cut while being unwound from a long roll. A roll laminator can be used for such a pasting operation.
[0035]
After bonding the polyimide film, a high-definition circuit pattern is formed on the surface opposite to the bonding surface by the above-described subtractive method, semi-additive method, or full-additive method. In particular, in order to obtain a high-definition circuit pattern, it is preferable to employ a semi-additive method or a full additive method.
[0036]
Furthermore, connection holes can be provided in the polyimide film. That is, it is possible to provide a via hole for electrical connection with the metal layer provided on the bonding surface side with the glass substrate, or to provide a ball mounting hole for the ball grid array. As a method for providing the connection hole, laser drilling such as a carbon dioxide laser, YAG laser, or excimer laser, or chemical etching can be employed.
[0037]
In the case of employing laser etching, it is preferable that a metal layer is present on the glass film attachment surface side of the polyimide film as an etching stopper layer. As the chemical etching solution for the polyimide film, hydrazine, potassium hydroxide aqueous solution, or the like can be used. Further, a patterned photoresist or a metal layer can be employed as the chemical etching mask. When electrical connection is made, it is preferable that after the connection hole is formed, the inner surface of the hole is made into a conductor by plating at the same time as the formation of the metal layer pattern. By forming high-precision circuit patterns on both sides and providing connection holes between them, the degree of freedom in wiring design is greatly improved. For example, taking advantage of the capability of high-definition circuits, ground wiring and power supply wiring are arranged on both sides of the signal line, and a relatively wide power supply wiring is connected to the ground level input electrode of the LSI chip from the other side. By arranging them close to each other and supplying them to the LSI chip through the connection holes, it becomes easy to greatly reduce the distortion of the signal waveform.
[0038]
The diameter of the connection hole for electrical connection is preferably 15 μm to 200 μm. The diameter of the hole for ball installation is preferably 50 μm to 800 μm.
[0039]
In particular, it is preferable to form the connection hole from the surface opposite to the bonding surface of the flexible film with the glass substrate.
[0040]
Next, the polyimide film on which the circuit pattern is formed is peeled from the glass substrate. Use a laser, high-pressure water jet, cutter, etc. to cut the polyimide film with a circuit pattern into individual pieces or a collection of individual pieces before peeling so that the circuit pattern can be easily handled with an apparatus for mounting electronic components. It is preferable to keep it. Moreover, when it is made small like an individual piece or an aggregate of individual pieces, it is preferable that stress does not remain on the polyimide film.
[0041]
Furthermore, in order to maintain the positional accuracy of the connection with the electronic component, it is preferable to peel the film from the glass substrate after connecting the electronic component to the circuit pattern on the polyimide film. As a connection method with an electronic component, solder connection, connection using an anisotropic conductive film, connection using a metal eutectic, connection using an isotropic non-conductive adhesive, wire bonding connection, or the like can be employed.
[0043]
In the above example, the circuit pattern formation on one surface of the flexible film was performed in a state where the other surface was not attached to the glass substrate, but a particularly high-definition circuit pattern was formed on both surfaces of the flexible film. In the case of forming, it is desirable that it is bonded to the glass substrate also in the processing of the surface where the circuit pattern is first formed. In this case, first, the surface to be processed after the flexible film is bonded to the glass substrate, and the opposite surface is formed with a circuit pattern by a subtractive method, a semi-additive method or a full additive method, and then another glass. After the circuit forming surface side is bonded to the substrate, the glass substrate first bonded is peeled off, and the subtractive method, semi-additive method or full additive method is applied to the surface on the side where the reinforcing plate of the flexible film is peeled off. Then, a circuit pattern is formed. Thereafter, the glass substrate attached later is peeled off.
[0044]
In the process of peeling the glass substrate only on one side from the state where the glass substrate is attached to both surfaces of the flexible film, the peelable organic layer is a type in which the adhesive force and the adhesive force are reduced by ultraviolet irradiation, In addition, it is preferable that the flexible film has a property of blocking ultraviolet rays or that there is a solid metal layer on the flexible film, and this metal layer blocks ultraviolet rays.
[0045]
The circuit board obtained by the method for producing a circuit board of the present invention is preferably used for a wiring board of an electronic device, an interposer for IC package, and the like. It is permissible as appropriate to insert a resistance element or a capacitance element into the circuit pattern.
[0046]
【Example】
Hereinafter, the present invention will be described more specifically with reference to examples, but the present invention is not limited thereto. In the present invention, the Young's modulus is a value determined according to JIS R1602.
[0047]
  referenceExample 1
  An adhesive for improving the adhesion of the metal layer was prepared as follows. The inside of the flask was replaced with a nitrogen atmosphere, 228 g of N, N-dimethylacetamide was added, and 19.88 g of 1,1,3,3-tetramethyl-1,3-bis (3-aminopropyl) disiloxane was dissolved. Next, 25.76 g of 3,3 ′, 4,4′-benzophenonetetracarboxylic dianhydride was added, and the mixture was stirred at 10 ° C. for 1 hour in a nitrogen atmosphere. Then, it was made to react, stirring at 50 degreeC for 3 hours, and the adhesive agent which consists of a polyimide precursor varnish was obtained.
[0048]
Using a comma coater, the adhesive was continuously applied to both sides of a long polyimide film having a thickness of 25 μm and a width of 300 mm (“UPILEX” manufactured by Ube Industries, Ltd.). Then, it was dried at 80 ° C. for 10 minutes, 130 ° C. for 10 minutes, 150 ° C. for 15 minutes, and cured at 250 ° C. for 5 minutes. The film thickness of the adhesive layer after curing was 1 μm. Five polyimide films with different lots were prepared.
[0049]
Next, a 50 nm thick chromium-nickel alloy film and a 100 nm thick copper film were laminated on the adhesive layer in this order by sputtering. The alloy film is provided on the bonding surface side of the polyimide film with the reinforcing plate. Using the alloy film as an electrode, electrolytic plating was performed in a copper sulfate solution to form a copper plating film having a thickness of 8 μm.
[0050]
A mixture of 0.7mm thick and 300mm square aluminoborosilicate glass mixed with weak adhesive re-peeling agent "SK Dyne" 1491 and curing agent L45 (manufactured by Soken Chemical Co., Ltd.) at 75: 1. It was applied and dried at 90 ° C. for 2 minutes. The thickness of the re-release agent after drying was 20 μm. Next, an air barrier film made of a film in which a silicone resin layer that is easy to release is provided on a polyester film is attached to the re-release agent layer (aluminoborosilicate glass / re-release agent layer / silicone resin layer / polyester film). Composition) I stayed for a week. The Young's modulus of the glass substrate is 7140 kg / mm²And Young's modulus (kg / mm²) And the cube of thickness (mm) was 2449 kg · mm.
[0051]
While peeling off the air blocking film consisting of the polyester film and the silicone resin layer, the polyimide film on which the copper plating film is formed with the roll type laminator on the glass on which the re-release agent layer is formed, the copper plating film surface is the glass substrate Affixed to face. At this time, the tension applied to the polyimide film was 500 g.
[0052]
Next, a carbon dioxide laser was used to form connection holes having a diameter of 100 μm arranged in a lattice pattern at a pitch of 10 mm. The connection hole is formed from the opposite surface of the polyimide film glass substrate attachment surface, and reaches the copper plating film on the attachment surface side.
[0053]
A chromium-nickel alloy film having a thickness of 50 nm and a copper film having a thickness of 100 nm were laminated in this order on an adhesive layer provided on the surface opposite to the bonding surface. A positive photoresist was applied onto the copper film with a spin coater and dried at 80 ° C. for 10 minutes. Substrate The photoresist was exposed through a photomask. The photoresist was developed to form a resist layer having a thickness of 10 μm in a portion where a plating film was unnecessary. The test photomask pattern was a black-and-white reversal of a pattern in which a circular pattern with a diameter of 300 μm and a circular pattern with a diameter of 300 μm was repeatedly formed in a lattice pattern having a line width of 10 μm and a pitch of 500 μm and a 10 mm pitch laser. That is, a grid-like plating pattern and a circular pattern with a pitch of 10 mm are obtained. After development, it was post-baked at 120 ° C. for 10 minutes. Next, electrolytic plating was performed using the copper film as an electrode. The electrolytic plating solution was a copper sulfate plating solution. After forming a copper plating film with a thickness of 6 μm, the photoresist is stripped with a photoresist stripping solution, and then the metal layer under the resist layer is removed by soft etching with an aqueous iron chloride solution to form a metal layer pattern. Obtained. A dry film resist was laminated so that the metal layer pattern was not etched in the patterning step of the copper plating film on the bonding surface with the glass substrate.
[0054]
The polyimide film laminated with the dry film resist was vacuum-adsorbed and gradually peeled off from the glass substrate from the end.
[0055]
A dry film resist was laminated on the copper plating film on the bonding surface with the glass substrate, and the dry film resist was exposed and developed through a photomask having a predetermined pattern to form a dry film resist pattern. A polyimide film on which a dry film resist pattern was formed was immersed in a copper etching solution of iron chloride, and the copper film was patterned, and at the same time, the chromium-nickel alloy film under the copper film was also patterned. Finally, the dry film resist on both sides was stripped with a stripping agent.
[0061]
  Example1
  referenceIn the same manner as in Example 1, a copper plating film having a thickness of 8 μm was formed on one side of the polyimide film. Before being attached to the glass substrate, the copper plating film was patterned by a subtractive method using a dry film resist and an etching solution. The remaining area ratio of the copper plating film was 50%.
[0062]
  referenceA polyimide film on which a copper plating film was formed was attached to a glass substrate with a weak adhesive re-release agent produced in the same manner as in Example 1 with a roll laminator so that the copper plating film surface was opposed to the glass surface.
[0063]
Next, a carbon dioxide laser was used to form connection holes having a diameter of 100 μm arranged in a lattice pattern at a pitch of 10 mm. The connection hole is formed from the opposite side of the polyimide film glass substrate attachment surface and reaches the copper plating film on the attachment surface side.
[0064]
  referenceIn the same manner as in Example 1, a wiring pattern made of a copper plating film having a thickness of 6 μm was obtained on the surface opposite to the bonding surface by a semi-additive method.
[0065]
The polyimide film was vacuum-adsorbed and gradually peeled from the glass substrate from the edge.
[0066]
With the length measuring device SNIC-800 (manufactured by Sokkia Co., Ltd.), the position of the intersection of the grid-like metal pattern was measured as the point where the center lines of the intersecting metal layer lines intersect. When measuring the distance of two points that were originally about 283 mm apart in the diagonal direction (200 mm in the x direction and 200 mm in the y direction), all the 5 different polyimide films were within ± 5 μm from the photomask pattern. It was very good.
[0067]
  Example2
  Example except that the remaining area ratio of the copper plating film formed on the glass substrate bonding surface was 25%1In the same manner, a double-sided wiring board was obtained.
[0068]
  With the length measuring device SNIC-800 (manufactured by Sokkia Co., Ltd.), the position of the intersection of the grid-like metal pattern was measured as the point where the center lines of the intersecting metal layer lines intersect. When measuring the distance of two points that were originally about 283 mm apart in the diagonal direction (200 mm in the x direction and 200 mm in the y direction), there was a case where the photomask pattern contracted by 25 μm.1The target high-definition pattern was obtained although it was inferior to this.
[0069]
  Comparative Example 1
  referenceIn the same manner as in Example 1, an adhesive was applied to a polyimide film having a thickness of 25 μm and a width of 300 mm, dried and cured. Instead of sticking the polyimide film to the glass substrate, except that the dry film resist is pasted as a protection of the copper plating film,referenceIn the same manner as in Example 1, circuit patterns were formed on both sides of a 300 mm square polyimide film.
[0070]
With the length measuring device SNIC-800 (manufactured by Sokkia Co., Ltd.), the position of the intersection of the grid-like metal pattern was measured as the point where the center lines of the intersecting metal layer lines intersect. When measuring the distance of two points that were originally about 283 mm apart in the diagonal direction (200 mm in the x direction and 200 mm in the y direction), the photomask pattern was distorted by 110 μm toward the outside of the substrate. . Even a relatively rough machining with a pitch of 200 μm or more was a problem.
[0071]
  Comparative Example 2
  Except that the thickness of the copper plating film formed before bonding the polyimide film to the glass substrate is 3 μm,referenceA double-sided wiring board was produced in the same manner as in Example 1. When the polyimide film on which the copper plating film is formed is pasted to the glass on which the re-release agent layer is formed, the polyimide film is stuck on the glass in a state where it is stretched by the tension of 500 g applied to the film. When the polyimide film is peeled off from the glass substrate, the stress applied to the polyimide film is released and shrinks toward the original state.
[0072]
With the length measuring device SNIC-800 (manufactured by Sokkia Co., Ltd.), the position of the intersection of the grid-like metal pattern was measured as the point where the center lines of the intersecting metal layer lines intersect. The distance between two points that were originally approximately 283 mm apart in the diagonal direction (200 mm in the x direction and 200 mm in the y direction) was measured, and the inside of the substrate with respect to the photomask pattern exposed in the state of being bonded to the glass There was one that was reduced by 50 μm toward the surface, which was defective.
[0073]
【The invention's effect】
According to the method for manufacturing a circuit board of the present invention, after a metal layer having a thickness of 5 μm or more is formed on at least one surface of the flexible film, the reinforcing plate can be peeled off on at least one surface of the exposed metal layer. After laminating through the organic layer, and then forming a circuit pattern on one side, the flexible film is peeled off from the reinforcing plate, so heat treatment process in processing step, expansion and contraction by wet process, or tension or Suppressing deformation due to external forces such as twisting, enabling fine processing closer to the design value. In particular, it is highly effective in improving the accumulative accuracy related to the alignment accuracy between the electrode pad and the circuit board pattern when connecting an electronic component such as an IC.

Claims (5)

After forming a metal layer having a thickness of 5 μm or more on at least one surface of the flexible film, and then patterning one metal layer of the surfaces on which the metal layer is formed, the patterned metal layer forming surface The reinforcing plate is bonded to one surface through a peelable organic material layer, and then a circuit pattern is formed on the surface where the reinforcing plate is not bonded, and then the flexible film is peeled from the reinforcing plate. A method of manufacturing a circuit board, characterized in that The method for manufacturing a circuit board according to claim 1, further comprising a step of forming a connection hole from a surface opposite to the surface to be bonded to the reinforcing plate of the flexible film. The method of manufacturing a circuit board according to claim 1, wherein the product of the cube of Young's modulus (kg / mm ² ) and thickness (mm) of the reinforcing plate is in the range of 2 kg · mm to 860000 kg · mm. The method for manufacturing a circuit board according to claim 1, wherein the reinforcing plate is glass. 2. The method of manufacturing a circuit board according to claim 1, wherein the remaining area ratio of the metal layer on the surface that is patterned and bonded to the reinforcing plate is 50% or more.