JPH0221157B2 - - Google Patents

Description

[Detailed description of the invention]

(Industrial Application Field) The present invention relates to a method for manufacturing a ceramic multilayer laminate made by laminating and firing a plurality of ceramic green sheets. It is used as a wiring board. (Prior art) Conventionally, as a manufacturing method for multilayer wiring boards and semiconductor packages used for high-density wiring boards, ceramic green sheets made of alumina, beryllia, etc. are molded by slip casting in the doctor blade method. A through hole is formed while cutting to a predetermined size, and a required pattern is formed on the through hole and the main surface of the ceramic green sheet using a metallization paste made of a high melting point metal such as Mo or W. A ceramic green sheet with a conductor pattern is heated to, for example, around 100℃,
Laminated by thermocompression bonding with a pressure of around 400Kg/ ^cm2 ,
After the ceramic green sheets are integrated, they are fired in a reducing atmosphere such as a hydrogen furnace, and the conductor pattern on the ceramic surface is plated with Ni or plated with Ni.
A method of applying augmenting is widely known. (Problem to be Solved by the Invention) However, in the process of laminating ceramic green sheets, voids are likely to form between the conductor patterns interposed between each layer, and in order to bond these well, it is necessary to apply pressure or pressure. It is necessary to raise the temperature. However, excessive pressure or temperature can deform the ceramic green sheet. Therefore, it is necessary to consider this amount of deformation and the gap between the green sheets during thermocompression bonding.
In cases where high dimensional accuracy is required and the amount of deformation is to be reduced, such as in high-density wiring boards and semiconductor packages, voids are likely to be formed. In addition, if the ceramic green sheet is water-soluble, the hardness of the ceramic green sheet changes depending on humidity, so the green sheet is made stiffer in advance to reduce the influence of humidity. Voids are likely to occur, making lamination difficult. Therefore, water-soluble green sheets have the disadvantage that temperature and pressure conditions must be varied due to variations in humidity during processing. Furthermore, in the case of water-soluble green sheets, the surface of the green sheet easily absorbs water and repels the water-insoluble conductive paste printed on it, so pinholes are likely to form in this paste during firing. be. The object of the present invention is to produce a ceramic multilayer laminate that can be laminated well without creating voids between the layers during lamination, and that can be laminated by thermocompression bonding under certain conditions without causing sheet deformation. I'm trying to provide a method. (Means for solving the problems) The method for manufacturing a ceramic multilayer laminate of the present invention includes:
A surface layer is formed on the surface of the ceramic green sheet, and the inorganic component is the same or similar to that of the ceramic green sheet, and the resin component is different from that of the ceramic green sheet. Next, through holes are formed, and then a conductive paste is applied inside the through holes. It is characterized by filling or applying a conductive paste to the inner wall, then applying the conductive paste to the ceramic green sheet or the surface layer, and then stacking a plurality of sheets with the surface layer remaining and firing. Preferably, the resin component of the surface layer of the ceramic green sheet is a resin having a lower softening point than the resin component of the ceramic green sheet, and is further water-insoluble. (Function) According to the present invention, since the resin component of the surface layer on the ceramic green sheet is made to have a lower softening point than the resin component of the ceramic green sheet,
When laminating ceramic green sheets by thermocompression bonding, the surface layer is softened by heating and pressing at a temperature higher than the softening point of the surface layer, and this softened surface layer is layered onto the ceramic green sheet or surface layer. It elastically covers the printed conductor pattern and is tightly adhered to the conductor pattern. Furthermore, if the surface layer is applied after punching through holes in the ceramic green sheet, via holes will be formed avoiding the through holes due to conduction, and lamination will likely peel off in the avoided areas, but according to the present invention, After forming the surface layer, the through-holes are formed, and the surface layer is present in all areas other than the through-hole portions, and no lamination peeling occurs.
Furthermore, there is no need for the via holes to become clogged during printing, and stable conduction can be achieved. Further, when the resin component of the ceramic green sheet is water-soluble, by making the surface layer non-water-soluble, the wettability with the metallization paste is improved, that is, the adhesion of the metallization paste is improved. (Example) Examples of the present invention will be described below based on the drawings. The cross-sectional views shown in FIGS. 1 and 2 represent the manufacturing process of a multilayered ceramic green sheet used in the present invention. The manufacturing process will be explained below in order. As shown in FIG. 1a, a ceramic green sheet 1 mainly composed of alumina, beryllia, etc.
It is prepared by a known doctor blade method and cut into required dimensions. This ceramic green sheet 1 has water-soluble or water-insoluble properties depending on the organic solvent or organic binder mixed with the ceramic component. In this ceramic green sheet 1, as shown in FIG.
As shown in FIG. 2, the surface layer 2 having different resin components is provided, for example, by a reverse coaster method. This surface layer 2 is made of, for example, a water-insoluble resin with strong adhesive strength that softens below the heating temperature during lamination by thermocompression bonding. Next, if necessary, a multilayer structure, in this example a ceramic green sheet 1, is applied, as shown in FIG. 1c.
A through hole 3 is provided in the through hole 3, as shown in FIG. A conductive paste 4 containing as a main component is filled. At this time, it is important to provide the through holes after forming the surface layer; otherwise, due to conduction problems, via holes must be formed in the surface layer avoiding the through holes. However, forming a via hole tends to cause problems such as poor adhesion or poor conduction in the recessed portion of the via, or poor conduction due to misalignment of the via or disappearance of the via. Furthermore, in order to form vias, the method of forming the surface layer is limited to screen printing or the like, which generally requires more man-hours and increases costs. Further, as shown in FIG. 1e, around each opening of the through hole 3, a conductive paste 5 made of the above-mentioned high melting point metal is formed by, for example, screen printing. This screen-printed conductive paste 5 and the conductive paste 4 filled in the through hole 3 are electrically connected. In the multilayered ceramic green sheet 1 thus formed, the thickness of the surface layer 2 is appropriate depending on the thickness of the conductive paste 5. For example, when the conductive paste 5 has a thickness of 20μ, In contrast, the surface layer 2 can have a thickness of approximately 10-30μ. However, if the thickness of this surface layer 2 is excessive, for example, it may cause warping during firing.
If the amount is too small, there will be an inconvenience that voids will be formed between the conductive pastes 5. Note that this surface layer 2
is provided only on one side on which the ceramic green sheets 1 are laminated, but depending on the properties of the ceramic green sheets 1, it may be necessary to provide them on both sides. For example, if the ceramic green sheet 1 is water-soluble, the ceramic green sheet 1
Since adhesion between the conductive paste 5 and the conductive paste 5 is poor, it is recommended to provide a water-insoluble surface layer 2 between the ceramic green sheet 1 and the conductive paste 5 in order to improve the adhesion of the water-insoluble conductive paste 5. suitable. For example, three ceramic green sheets 1 thus formed are thermocompression bonded under predetermined temperature and pressure conditions to form an integral laminate, as shown in FIGS. 2a and 2b. During this thermocompression bonding, the surface layer 2 is heated and softened at a temperature above its softening point, and this softened surface layer 2 makes the conductive paste 5 between the surface layer 2 and the ceramic green sheet 1 elastic. It covers the conductive paste 5 and penetrates into the gaps between each ceramic green sheet 1.
Each ceramic green sheet 1 is closely attached with no unevenness between the ceramic green sheets 1. Therefore, no voids are created between the conductive pastes. In addition, at least one adhesive surface layer 2 is interposed between each ceramic green sheet 1, which acts as an adhesive and improves the adhesion between the ceramic green sheets. can also be lowered. Next, this integrated ceramic multilayer laminate is fired in a reducing atmosphere to form a sintered body, as shown in FIG. 2c. At this time, if the ceramic multilayer laminate is tightly bonded to each other in the unfired state and there are no gaps between the layers, the ceramic multilayer laminate will be fired as one piece and no adhesion failure or peeling will occur. This fired ceramic multilayer laminate is finally plated with Ni and Au to form a ceramic multilayer wiring board. Next, an actual manufacturing example will be described below. Example 1 First, 5.5 parts of polyvinyl butyral, which softens at about 120°C, and dibutyl phthalate are added to 100 parts by weight of a ceramic component, which is a mixture of 90% by weight of alumina and 10% by weight of additives such as silica and magnesia. Alternatively, mix 2 parts of dioctyl phthalate with an organic solvent such as toluene or isopropyl alcohol to make a slurry of 8000 cps, then form a ceramic green sheet with a thickness of 0.6 mm using a doctor blade method, and then add 100 parts of the above ceramic component. Polyvinyl butyral 15, which softens at about 60℃
A slurry of 5,000 cps was prepared by mixing the sample and an organic solvent, and then a surface layer with a thickness of about 20 μm was formed on one side of a ceramic green sheet using a reverse coaster method. Next, a through hole is formed using a through hole punch, and a conductive paste containing molybdenum as a main component is filled in the through hole. After forming a pattern using screen printing with the conductive paste containing tungsten as a main component, the above-mentioned Multiple layers of ceramic green sheets are stacked at a temperature of 80℃,
Pressure was applied for 1 minute at a pressure of 20 kg/cm ² . At this point, a complete multilayer stack was formed, with no voids between conductor patterns or otherwise. Further, no elongation of the green sheet was observed. Then in a reducing atmosphere (e.g. hydrogen furnace)
Alumina ceramics, which is an insulator, and W and Mo, which are conductors, were simultaneously fired by holding at 1570°C for 2 hours to obtain an integrated multilayer laminate. Next, Ni plating is applied to the metal parts exposed from the co-fired multilayer laminate, and then Au plating is applied to create ceramic multilayer wiring that can be used for wire bonding and soldering of semiconductor chips, or for brazing external connection terminals. A substrate was formed. In this example, since both the ceramic green sheet and the surface layer have water-insoluble properties, even when the conductive paste is applied to both layers, the paste sticks well and pinholes are unlikely to form. There is a characteristic that Example 2 Ceramic component 100 with the same components as in the previous example
6 parts of methyl cellulose, which softens at about 150°C, is mixed with water to make a slurry of 30,000 cps, and then a ceramic green sheet with a thickness of 0.6 mm is formed using the doctor blade method. For the surface to be laminated as a component, use the amount of polyvinyl butyral that softens at 60℃ as shown in Table 1, and for the surface that is not laminated, use 7 parts of polyvinyl butyral that softens at 120℃, and mix these with an organic solvent to produce 5000 cps. After making the slurry, a surface layer with a thickness of about 15 μm was formed on both sides of the ceramic green sheet using the reverse coaster method.

[Table] Next, a through hole was formed using a through hole punch, and a conductive paste containing molybdenum as a main component was filled in the through hole, and then a pattern was formed using the conductive paste containing tungsten as a main component by screen printing. After that, multiple layers of the ceramic green sheets were stacked and heated at a temperature of 80°C.
Pressure was applied for 2 minutes at a pressure of 20 kg/cm ² . At this point, when the amount of resin is 13 parts or more, the conductor paste has a through hole that completely connects the upper and lower conductor pastes.
A multilayer laminate was formed. The lamination properties at this time are shown in Table-1. Further, no elongation of the green sheet was observed. Thereafter, it was fired in a reducing atmosphere in the same manner as in the previous example to obtain a monolithic ceramic multilayer laminate. Metal parts exposed from this ceramic multilayer laminate were plated with Ni and Au to form a ceramic multilayer wiring board. In this example, the ceramic green sheet has a sandwich structure sandwiched between two surface layers, but this is because the ceramic green sheet is a water-soluble resin, so the water-soluble ceramic green sheet has a water-insoluble resin. By providing the surface layer, the adhesion of the conductive paste is improved, the occurrence of pinholes etc. after printing is prevented, and stability is increased against fluctuations in ambient humidity. In addition, since surface layers are provided on both sides of the ceramic green sheets, two surface layers are interposed between these ceramic green sheets and cover the conductive paste during lamination, so that the surface layer is similar to that in Example 1. thickness is not required. The present invention is not limited to the embodiments described above, and can be modified and changed in many ways. (Effects of the Invention) As is clear from the above detailed explanation, according to the present invention, by further providing an adhesive surface layer on the ceramic green sheet, the lamination process is simplified, and the heating Temperature and pressure can be reduced compared to conventional methods,
The ceramic green sheet will not be deformed. Furthermore, since the surface layer is water-insoluble, it is possible to closely stack the conductor patterns without forming pinholes. Furthermore, the layers can be stacked under almost constant conditions regardless of seasonal changes in humidity.

[Brief explanation of drawings]

FIGS. 1A to 1E are cross-sectional views showing the steps of forming the ceramic green sheets of the present invention, and FIGS. 2A to C are cross-sectional views showing the steps of laminating the ceramic green sheets of the present invention. 1... Ceramic green sheet, 2... Surface layer, 3... Through hole, 4, 5... Conductive paste.

Claims (1)

[Claims] 1. When producing a ceramic multilayer laminate by laminating and firing ceramic green sheets, the surface of the ceramic green sheets has an inorganic component that is the same or similar to that of the ceramic green sheets, and a resin component that is the same as or similar to the ceramic green sheets. After forming a different surface layer with the ceramic green sheet, then forming a through hole, filling the inside of the through hole with conductive paste or applying the conductive paste on the inner wall, and then applying it to the ceramic green sheet or the surface layer. A method for manufacturing a ceramic multilayer laminate, which comprises applying a conductive paste, laminating a plurality of ceramics with a surface layer remaining, and firing. 2. The method of manufacturing a ceramic multilayer laminate according to claim 1, wherein the resin component of the surface layer of the ceramic green sheet is a resin having a lower softening point than the resin component of the ceramic green sheet. 3. The method for manufacturing a ceramic multilayer laminate according to claim 1 or 2, wherein the resin component of the ceramic green sheet is water-soluble, and the resin component of the surface layer is water-insoluble.