JP3872284B2 - Manufacturing method of glass ceramic substrate - Google Patents

Description

【００８２】
表１から、実施例４〜７の各密着剤を使用して得られたガラスセラミック基板は焼成時の収縮が抑制され、高い寸法精度を有していることがわかる。なお、表１に示す結果中、反りはレーザ光学式非接触３次元形状測定装置を用いて反り高さを測定したものである。
【００８３】
（実施例８）
研磨材粒子を平均粒径30μｍのガラスビーズ（球状ガラス粉末）に変更した以外は実施例７と同様にしてガラスセラミック基板を得た。その結果、実施例７と同様の良好な基板が得られた。
（実施例９）
研磨材粒子を平均粒径50μｍに、ブラストエアー圧力を0.1ＭＰａに変更した以外は実施例５と同様にしてガラスセラミック基板を得た。実施例５と同様の良好な基板が得られた。
（比較例４）
研磨材粒子を平均粒径100μｍのユリア樹脂に変更した以外は実施例５と同様にしてガラスセラミック基板を得た。ブラストエアー圧力を上げることにより、拘束シートの除去ができた。
【００８４】
（比較例５〜７）
研磨材の平均粒径を100μｍ、75μｍおよび3μｍに変更した以外は実施例７と同様にしてガラスセラミック基板を得た。
【００８５】
平均粒径が100μｍの場合はメタライズ導体が一部剥がれる場合があった。これは、研磨材粒子の粒径が大きくなり質量も大きくなったために研磨力が大きくなったからである。なお、ブラストエアー圧力を下げることにより、拘束シートの除去とメタライズ導体の剥がれとの実用的なバランスを取ることは可能であった。
【００８６】
平均粒径が75μｍの場合はブラストエアー圧力を0.1ＭＰａにした時にほぼ完全に拘束シートを除去できた。この場合、メタライズ導体表面の表面粗さＲｍａｘが５μｍ程度となり、メタライズ表面を観察するとやや大きな窪みの発生が認められた。これはメタライズ表面に粒径の比較的大きな研磨材粒子が当たった痕跡であると考えられる。
平均粒径が３μｍの場合は短時間では十分な除去がやや困難であった。ブラストエアー圧力をあげると除去性は上がるが、圧力が高いためにメタライズ導体へのダメージも大きくなる傾向があり、メタライズ導体が一部膨れる場合も見られた。なお、処理時間を長くすることにより、良好な表面状態での拘束シートの除去は可能であった。
【００８７】
（比較例８）
研磨材粒子を球状でない多角形の研磨材粒子に変更した以外は実施例５と同様にしてガラスセラミック基板を得た。この場合、メタライズ導体表面を観察すると、付着した拘束シートは除去されたが、メタライズ導体上に研磨材粒子が突き刺さった状態で残っている場合があった。なお、処理条件を適切に調整することにより、良好な表面状態での拘束シートの除去は可能であった。
【００８８】
【発明の効果】
本発明によれば、ガラスセラミック・グリーンシート積層体の両面に、焼成時に結合剤として働くガラスを含む密着剤層を介してこの積層体と結合し、かつ焼成時に実質的に収縮しない拘束グリーンシートを積層して焼成するので、ガラスセラミック・グリーンシート基板の積層面内の収縮を確実に抑えることができ、焼成後の拘束シートと密着材層を液体と研磨材粒子と気体との混合物を投射して除去するので、反りや変形がなく、かつ拘束シートの付着残留物や基板表面へのダメージがない、寸法精度の高い良好な表面状態のガラスセラミック基板が得られるという効果がある。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for manufacturing a multilayer glass ceramic substrate for mounting semiconductor LSIs, chip parts, and the like and interconnecting them.
[0002]
[Prior art]
In recent years, semiconductor LSIs, chip parts, and the like have been reduced in size and weight, and wiring boards on which these are mounted are also desired to be reduced in size and weight. In response to such demands, multilayer ceramic substrates with internal electrodes and the like arranged in the substrate are required in today's electronics industry because they enable the required high-density wiring and can be made thinner. Yes.
[0003]
As a multilayer ceramic substrate, an insulating substrate made of an alumina sintered body and having a wiring layer made of a refractory metal such as tungsten or molybdenum formed on the surface or inside thereof has been widely used.
[0004]
On the other hand, with the recent advanced information age, the frequency bands used are increasingly shifting to higher frequencies. In a high-frequency wiring board that transmits such a high-frequency signal, the resistance of the conductor forming the wiring layer is required to be small in order to transmit the high-frequency signal at high speed, and the insulating substrate also has a lower dielectric constant. Required.
[0005]
However, conventional refractory metals such as tungsten (W) and molybdenum (Mo) have high conductor resistance, low signal propagation speed, and difficulty in signal propagation in a high frequency region of 30 GHz or more. It is necessary to use a low resistance metal such as copper (Cu), silver (Ag), or gold (Au) instead of the metal such as. However, since the low resistance metal as described above has a low melting point, it is necessary to fire at a low temperature of about 800 to 1100 ° C. Therefore, the wiring layer made of the low resistance metal is made of alumina that requires high temperature firing. Simultaneous firing was not possible. Moreover, since the alumina substrate has a high dielectric constant, it is not suitable for a high-frequency circuit substrate.
[0006]
For this reason, recently, attention has been focused on using glass ceramics obtained by firing a mixture of glass and ceramics (inorganic filler) as an insulating substrate. That is, glass ceramics are suitable as high-frequency insulating substrates because of their low dielectric constant, and glass ceramics can be fired at a low temperature of 800 to 1100 ° C., so low resistance metals such as copper, silver, and gold are used as wiring layers. As an advantage.
[0007]
Multi-layer glass ceramic substrate is made by adding organic binder, plasticizer, solvent, etc. to a mixture of glass and filler to form a slurry, and after forming glass ceramic green sheet by doctor blade etc., low resistance such as copper, silver, gold etc. A conductive paste containing metal powder is printed to form a conductive pattern on the green sheet, and then a plurality of green sheets are laminated and fired at a temperature of 800 to 1100 ° C.
[0008]
However, the multi-layer glass ceramic substrate has a problem that shrinkage occurs during sintering during sintering. The degree of such shrinkage is not uniform, and the shrinkage rate and shrinkage direction differ depending on the inorganic material for the substrate to be used, the green sheet composition, the variation in powder particle size as the raw material, the conductor pattern, the internal electrode material, and the like. This causes several problems in the production of multilayer glass ceramic substrates.
[0009]
First, when producing a screen plate for printing internal electrodes, the size of the screen plate must be determined by calculating backward from the shrinkage rate of the substrate. However, the shrinkage rate and shrinkage direction of the substrate are not constant as described above. The screen plate must be remade for each production lot of substrates, which is uneconomical and impractical. Furthermore, in the multilayer glass ceramic substrate produced by the green sheet laminating method as described above, the shrinkage rate in the vertical direction and the horizontal direction in the laminated surface differs depending on the film forming direction of the green sheet. It becomes even more difficult.
[0010]
On the other hand, when forming an electrode having an area larger than necessary so as to allow shrinkage error, high-density wiring cannot be made.
[0011]
In order to reduce these shrinkage changes, the trend of the shrinkage rate of the substrate by circuit design is investigated, the substrate material and green sheet composition management in the manufacturing process, powder particle size variation, lamination conditions such as press pressure and temperature, etc. Need to be well managed. However, it is generally said that there is an error of about ± 0.5% in shrinkage rate.
[0012]
This is a problem common to those associated with sintering of ceramics and glass ceramics regardless of the multilayer glass ceramic substrate. In order to solve such a problem, Japanese Patent Laid-Open No. 4-243978, Japanese Patent Laid-Open No. 5-28867, and Japanese Patent Laid-Open No. 5-102666 disclose a substrate including the following steps (1) to (4). Manufacturing methods have been proposed.
[0013]
(1) Laminate a desired number of glass ceramic green sheets containing a glass ceramic component and organic components such as a binder and a plasticizer in which a conductor pattern is formed,
(2) A constrained green sheet containing an inorganic material that does not sinter at the firing temperature of the glass ceramic component and an organic component such as a binder and a plasticizer is laminated on both sides or one side of the obtained glass ceramic green sheet laminate. And
(3) The laminated body of these glass ceramic green sheets and constrained green sea are heated to first remove organic components and then fired to form glass ceramic substrates and constraining sheets, respectively.
(4) Finally, the restraint sheet is removed from the glass ceramic substrate.
[0014]
According to this method, the constraining green sheet restrains the shrinkage during firing of the glass ceramic green sheet, so that the shrinkage occurs only in the thickness direction of the laminated body, and the shrinkage occurs in the vertical and horizontal directions of the laminated surface. This is considered to improve the dimensional accuracy of the glass ceramic substrate.
[0015]
[Problems to be solved by the invention]
In the above method, the glass ceramic green sheet and the constrained green sheet are bonded by an organic component such as a binder contained in the green sheet. However, in the firing step (3), after organic components such as binders and plasticizers decompose and volatilize, the powder in the constrained green sheet and the powder in the glass ceramic green sheet are simply in close contact with each other. Only weak bonds due to van der Waals forces are working between the sheets.
[0016]
Although such a weak bond has an advantage that the removal of the constraining sheet in the step (4) is easy, the constraining green sheet is thermally expanded from the glass ceramic green sheet laminate in the firing step (3). There is a risk of inadvertent peeling due to differences.
[0017]
If the constrained green sheet is peeled off during firing, sintering shrinkage of the glass ceramic green sheet cannot be prevented. Further, even if the constrained green sheet is partially peeled, the glass ceramic substrate is deformed due to contraction in the part.
[0018]
Also, since the glass ceramic / green sheet laminate and the constrained green sheet have a low bonding force, the glass component in the constrained green sheet in the glass ceramic / green sheet depends on the state of adhesion before firing and the type of glass ceramic component. Depending on the penetrability, the bond strength tends to be uneven. If the bonding force is uneven, the force that restrains the sintering shrinkage of the glass ceramic can be uneven, causing shrinkage unevenness, and warping, deformation, etc. of the glass ceramic substrate. As a result, there is a problem that a substrate with high dimensional accuracy cannot be obtained.
[0019]
Furthermore, as a method of removing the attached restraint sheet, scraping with a brush, ultrasonic cleaning, grinding, lapping, dry blasting (a method of projecting an abrasive to a target removal portion by high-pressure air flow), wet blasting (abrasive) In this method, there is a problem that the removability may not be sufficient.
For example, brushing and ultrasonic cleaning remove most of the constraining sheet, but there is a problem that particles in the constraining sheet tend to remain on the very surface of the porcelain. In particular, the restraint sheet on the metallized layer to which the restraint sheet easily adheres may not be sufficiently removed. In this case, there is a problem that the solder wettability and the plating property of the metallized layer are deteriorated.
In addition, grinding and lapping have a problem that local flaws tend to occur on the surface of the glass ceramic substrate after the restraint sheet is removed.
In dry blasting, the abrasive directly hits the glass ceramic substrate surface at high pressure, so the removal capability is high. However, the metallized layer formed on the glass ceramic substrate surface may be peeled off, or the abrasive may bite into the metallized layer. There was a problem that sometimes it was.
Furthermore, in wet blasting, the removal capacity may be weak because the water pool becomes a cushion, and the use of fine abrasives makes it difficult to use fine abrasives. The surface roughness of the later glass ceramic substrate surface tends to increase, and as a result, there is a problem that the plating property and wire bonding property of the metallized layer may be deteriorated.
[0020]
An object of the present invention is to provide a method for obtaining a glass ceramic substrate with high dimensional accuracy by reliably restraining the sintering shrinkage in the laminated surface of the glass ceramic green sheet so that there is no residue of restraint sheet deposits on the surface. Is to provide.
[0021]
[Means for Solving the Problems]
As a result of intensive studies to solve the above problems, the present inventors have (I) an adhesive layer containing a glass component interposed between a constrained green sheet and a glass ceramic green sheet. The glass component acts as a binding material for bonding the glass ceramic green sheet and the constraining green sheet in the firing process, so that the binding force between them can be increased and the constraining green sheet can be prevented from peeling off (II ) The glass component content in the adhesive layer is the amount removed from the glass ceramic substrate together with the constraining sheet after firing. As a result, (III) the constrained green sheet ensures the shrinkage of the glass ceramic / green sheet laminate. To obtain a glass ceramic substrate with high dimensional accuracy, and (IV) liquid, abrasive particles and gas The constraining sheet adhering to the surface of the glass ceramic substrate can be completely removed while suppressing damage to the conductor formed on the substrate surface, and a glass ceramic substrate with high dimensional accuracy is obtained. The present inventors have found a new fact that it is possible to complete the present invention.
[0022]
  That is, the method for producing a glass-ceramic substrate of the present invention comprises (i) laminating a plurality of glass-ceramic / green sheets containing an organic binder and having a conductor pattern formed on the surface to produce a glass-ceramic / green-sheet laminate. And (ii) a step ofA step of applying an adhesive containing glass and a solvent to a constrained green sheet containing a hardly sinterable inorganic material and an organic binder; iii )On both sides of the glass ceramic green sheet laminate,The coating was applied between the constrained green sheet and the glass ceramic green sheet laminate.Adhesive layerEstablishmentAndThe adhesive was appliedA step of laminating the restraining green sheets; (iv) Removing an organic component from the laminate of the constrained green sheet and the glass ceramic / green sheet laminate, and then firing to produce a glass ceramic substrate holding the restraint sheet;v) Projecting a mixture of liquid, abrasive particles and gas onto the constraining sheet to remove the constraining sheet from the glass ceramic substrate,vi) The glass content of the adhesive layer is such that the constraining green sheet is bonded to the glass ceramic green sheet during firing and removed from the glass ceramic substrate together with the constraining sheet after firing.The softening point of the glass contained in the adhesive is not higher than the firing temperature of the glass ceramic green sheet laminate.It is characterized by that.
[0023]
  In the present invention, the adhesionIn the medicineThe softening point of the glass contained in is preferably not higher than the firing temperature of the glass ceramic / green sheet laminate. As a result, the glass in the constrained green sheet is softened in the firing step, and the bonding strength is increased.
[0024]
  Also, the close contactIn the medicineThe softening point of the glass contained in is preferably higher than the removal temperature of the organic component. When the softening point of the glass is lower than the removal temperature of the organic component, the removal path for allowing the decomposed and volatilized organic component to pass through may be blocked by the softened glass.
[0025]
  Close contactIn the medicineThe glass content of the adhesiveFormulationIt should be 5 to 50% by weight of the minutes. Usually, this range does not impair the adhesion between the glass ceramic green sheet and the constrained green sheet during lamination, and is bonded to the glass ceramic green sheet during firing and is removed from the glass ceramic substrate together with the constraining sheet after firing. Become. When the amount is less than 5% by weight, the amount of glass that acts as a binder during firing is small, so that the binding between the constraining sheet and the glass ceramic green sheet becomes insufficient. When the amount is more than 50% by weight, the amount of glass is so large that the area where the constrained green sheet and the glass ceramic green sheet are in close contact with each other at the time of lamination may be reduced, resulting in poor adhesion before firing. Further, when removing the restraint sheet after firing, it is difficult to remove the restraint sheet because a strong glass layer is formed on the glass ceramic substrate. In addition, although glass content changes with kinds etc. of glass to be used, about 5 to 50 weight% is good.
[0026]
And in order to remove a restraint sheet | seat from the surface of a glass-ceramic board | substrate after baking, it is good to use the method of projecting the mixture of a liquid, abrasive particle, and gas. Since this method is a mixture of liquid, abrasive particles and gas, it becomes softer than dry blasting such as sandblasting, which directly projects only the abrasive, and the surface roughness of the glass ceramic substrate surface after processing is soft. The damage that becomes large can be suppressed. Further, compared with a wet blast such as a jet scrub that projects a mixture of liquid and abrasive particles, the polishing process power is excellent, and the same damage to the glass ceramic substrate surface can be suppressed. Therefore, the conductor formed on the substrate surface is not peeled off, the surface roughness of the substrate surface is increased, the surface roughness of the conductor surface is increased, and the plating property on the conductor and the wire bonding property are not deteriorated. The constraining sheet can be efficiently and completely removed in a short time, and a glass ceramic substrate having a good surface state can be obtained.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
The manufacturing method of the glass ceramic substrate of the present invention will be described in detail below.
[0028]
As the glass ceramic green sheet in the present invention, a glass powder, a filler powder (ceramic powder), an organic binder, a plasticizer, an organic solvent and the like are used.
[0029]
Examples of glass components include SiO.₂-B₂O_ThreeSystem, SiO₂-B₂O_Three-Al₂O_ThreeSystem, SiO₂-B₂O_Three-Al₂O_Three-MO system (where M represents Ca, Sr, Mg, Ba or Zn), SiO₂-Al₂O_Three-M¹OM²O system (however, M¹And M²Are the same or different and represent Ca, Sr, Mg, Ba or Zn), SiO₂-B₂O_Three-Al₂O_Three-M¹OM²O system (however, M¹And M²Is the same as above), SiO₂-B₂O_Three-M^Three ₂O system (however, M^ThreeRepresents Li, Na or K), SiO₂-B₂O_Three-Al₂O_Three-M^Three ₂O system (however, M^ThreeIs the same as above), Pb-based glass, Bi-based glass and the like.
[0030]
Further, as the filler, for example, Al₂O_Three, SiO₂, ZrO₂And TiO, a complex oxide of alkaline earth metal oxides₂Al oxide of alkaline earth metal oxide, Al₂O_ThreeAnd SiO₂And composite oxides containing at least one selected from (for example, spinel, mullite, cordierite).
[0031]
The mixing ratio of the glass and filler is a ratio used for a normal glass ceramic substrate material, and is preferably 40:60 to 99: 1 by weight.
[0032]
As the organic binder compounded in the glass ceramic green sheet, those conventionally used for ceramic green sheets can be used. For example, acrylic (acrylic acid, methacrylic acid or ester homopolymers or copolymers thereof are used. Polymer, specifically acrylic ester copolymer, methacrylic ester copolymer, acrylic ester-methacrylic ester copolymer, etc.), polyvinyl butyral, polyvinyl alcohol, acrylic-styrene, Examples thereof include homopolymers or copolymers such as polypropylene carbonate and cellulose.
[0033]
The glass ceramic green sheet is obtained by adding a predetermined amount of plasticizer and solvent (organic solvent, water, etc.) to the glass powder, filler powder, and organic binder as necessary to obtain a slurry, which is then used as a doctor blade, rolled, calendered. It can be obtained by molding to a thickness of about 50 to 500 μm with a roll, a die press or the like.
[0034]
In order to form a conductor pattern on the surface of a glass ceramic green sheet, for example, a paste of a conductor material powder is printed by a screen printing method or a gravure printing method, or a metal foil having a predetermined pattern shape is transferred. A method is mentioned. Examples of the conductor material include one or more of Au, Ag, Cu, Pd (palladium), Pt (platinum), and the like, and in the case of two or more, any form such as mixing, alloy, coating, etc. There may be.
[0035]
The conductor pattern on the surface includes a portion where a through conductor such as a via conductor or a through-hole conductor for connecting conductor patterns between upper and lower layers is exposed on the surface. These through conductors are formed by means such as embedding by printing a paste of conductive material powder (conductor paste) in a through hole formed in a glass ceramic green sheet by punching or the like.
[0036]
For the lamination of glass ceramic green sheets, heat and pressure are applied to the stacked green sheets by heat and pressure, and an adhesive composed of an organic binder, plasticizer, solvent, etc. is applied between the sheets and heat pressed. Can be adopted.
[0037]
The constrained green sheet in the present invention is obtained by molding a slurry obtained by adding an organic binder, a plasticizer, a solvent and the like to an inorganic component made of a hardly sinterable inorganic material. As a hardly sinterable inorganic material, Al₂O_ThreeAnd SiO₂Although at least 1 sort (s) chosen from these is mentioned, It is not restrict | limited to these.
[0038]
Moreover, you may make it contain the same glass component as an adhesion agent layer in a restraint green sheet, and may raise the bond strength of a restraint green sheet and a glass ceramic green sheet more. In this case, the amount of the glass component is preferably an amount that does not cause the constrained green sheet to substantially contract within the laminated surface during firing.
[0039]
The thickness of the constrained green sheet laminated on both sides of the glass ceramic green sheet is preferably 10% or more with respect to the thickness of the glass ceramic / green sheet laminate on one side only. There is a possibility that the restraint property of the green sheet is lowered. Further, in consideration of facilitating the volatilization of organic components and considering the removal of the restraint sheet from the glass ceramic substrate, the thickness of the restraint green sheet should be about 200% or less of the thickness of the glass ceramic / green sheet laminate. . Further, the constraining sheets to be laminated may be one sheet, or may be a plurality of sheets laminated to have a predetermined thickness.
[0040]
The constrained green sheet is obtained by molding using an organic binder, a plasticizer, a solvent and the like in the same manner as the production of the glass ceramic green sheet. As the organic binder, the plasticizer and the solvent, the same materials as those used for the glass ceramic green sheet can be used. Here, the plasticizer is added in order to impart flexibility to the constraining green sheet and to enhance adhesion with the glass ceramic green sheet during lamination.
[0041]
As the adhesive for forming the adhesive layer, a mixture of glass powder, organic solvent and the like is used. Furthermore, an organic binder component can be contained to increase the bonding strength between green sheets before firing, or to adjust the viscosity to be easy to apply. Moreover, a dispersing agent etc. can be added and the dispersibility of the glass in adhesive agent can also be improved.
[0042]
The glass in the adhesive is not particularly limited, and the same glass as that used in the glass ceramic green sheet can be used. Further, the glass in the adhesive may have the same composition as that of the glass in the glass ceramic green sheet, or may have a different composition.
[0043]
The softening point of the glass in the adhesive is preferably not higher than the firing temperature of the glass ceramic / green sheet laminate and higher than the decomposition / volatilization temperature of the organic components in the green sheet. Specifically, the softening point of glass in the adhesive is preferably about 450 to 1100 ° C. If the softening point of the glass is less than 450 ° C, the organic component is completely removed by removing the organic component from the decomposed and volatilized glass when the organic component is removed from the glass ceramic green sheet. It may not be possible. On the other hand, when the glass softening point exceeds 1100 ° C., it may not function as a binder to the green sheet under normal glass ceramic green sheet firing conditions.
[0044]
The particle size of the glass in the adhesive is desirably 10 μm or less. If it is larger than this, the glass particles may bite into the conductor pattern on the glass ceramic green sheet when the green sheet is laminated, which increases the surface roughness of the conductor after firing or causes defects in the conductor. It is because there is a possibility of doing. In the case where the constraining green sheet is softer than the conductor pattern and the glass bites into the constraining green sheet, there is no such limitation.
[0045]
The solvent in the adhesive is not particularly limited as long as it uniformly disperses the glass and does not impair the bonding between the green sheets. Also, a plurality of solvents can be mixed and used. It is preferable to use a material that imparts flexibility to the green sheet, or swells or dissolves the surface of the green sheet to increase the bonding force between the green sheets. Specifically, diethylene glycol monobutyl ether acetate ( BCA), di-n-butyl phthalate (DBP), di-2-sec-hexyl phthalate (DOP), terpineol, toluene, butyl acetate, ethyl acetate and the like. Different solvents may be used as appropriate solvents depending on the green sheet.
[0046]
In order to laminate the formed constrained green sheet on both surfaces of the glass ceramic green sheet, a method of forming an adhesive layer between the sheets and pressing, for example, is employed. For example, an adhesion agent is applied to a constrained green sheet by screen printing, laminated on a glass ceramic / green sheet laminate, and thermocompression bonded.
[0047]
After producing a laminate formed by laminating constrained green sheets, the organic components are removed and fired. The organic component is removed by heating the laminate in a temperature range of 100 to 800 ° C. to decompose and volatilize the organic component. Moreover, although a calcination temperature changes with glass-ceramic compositions, it is in the range of about 800-1100 degreeC normally. Firing is usually performed in the air, but when Cu is used as the conductor material, organic components are removed in a nitrogen atmosphere containing water vapor at 100 to 700 ° C., and then the firing is performed in a nitrogen atmosphere.
[0048]
Further, during firing, a load may be applied by placing a weight on the upper surface of the laminate in order to prevent warping. The load due to such weight is suitably about 50 Pa to 1 MPa. When the load is less than 50 Pa, there is a possibility that the effect of suppressing the warpage of the laminate is not sufficient. Also, if the load exceeds 1 MPa, the weight to be used will be large, so it will not be able to enter the firing furnace, or even if it enters the firing furnace, the weight will be large and the heat capacity will be insufficient and firing will occur. There is a risk of causing problems such as being unable to do so.
[0049]
This weight is a heat-resistant porous material that does not deform or melt during the firing of the glass-ceramic substrate to make the load non-uniform or to prevent volatilization of decomposed organic components. Is suitable. Specifically, a refractory material such as ceramics or a metal having a high melting point may be used. Further, a porous weight may be placed on the upper surface of the laminate, and a non-porous weight may be placed thereon.
[0050]
After firing, the constraining sheet is removed. Here, the adhesive layer can be removed together with the constraining sheet. In the present invention, the constraining sheet is removed by a method of projecting a mixture of liquid, abrasive particles and gas onto the constraining sheet. Specifically, for example, wet blasting is used in which a mixture (slurry) of an abrasive and water is pumped, and this is accelerated by air pressure and projected. At this time, a slurry obtained by mixing abrasive particles and water so that the amount of abrasive particles is usually about 10 to 30% by volume is used.
Abrasive particles are Al₂O_ThreeInorganic powders such as ceramic powder and glass powder are used, but in addition, various materials are polished according to the material of the substrate, the material of the metallized conductor formed on the surface, the material of the restraint sheet, the adhesion condition, etc. What is necessary is just to select suitably from material particle | grains.
The restraint sheet attached to the surface of the glass ceramic substrate is made of a hardly sinterable inorganic material, and since glass exists between the restraint sheet and the glass ceramic substrate, the material that is extremely softer than these deforms itself. In principle, it is preferable to use an inorganic powder such as a ceramic powder for the abrasive particles because the abrasive particles cannot be removed due to damage.
[0051]
Moreover, the shape without a corner | angular form, ie, the thing close | similar to a spherical shape, is preferable. This is because in a cornered shape, the surface of the glass ceramic substrate and the metallized conductor is easily damaged by the corner, and when the corner is an acute angle, the abrasive particles may bite into the metallized conductor. If an inorganic substance such as abrasive particles adheres to the metallized conductor, solder wettability, plating property, and wire bonding property are remarkably deteriorated.
The abrasive particles preferably have an average particle size of 5 to 50 μm. If the average particle diameter is larger than 50 μm, the polishing force becomes too large due to the large mass of the particles and the metallized conductor tends to be peeled off, and the surface roughness after the treatment increases, resulting in a metallized conductor. There is a tendency that the plating property and the wire bonding property to the top are lowered. On the other hand, if the average particle size is smaller than 5 μm, it tends to be difficult to remove the constraining sheet efficiently and completely in a short time.
[0052]
The pump pressure to send slurry and the blast air pressure that is the projection pressure vary depending on the shape and size of the nozzle of the projecting device, and this also depends on the material of the substrate, the material of the metallized conductor, the material of the restraint sheet, the degree of adhesion, etc. Adjust it. Usually, the blast air pressure is set in such a range that the constraining sheet, which is a deposit on the metallized conductor on the substrate and the substrate surface, can be removed and the metallized conductor is not peeled off or its adhesion strength is not reduced. In general, 0.05 MPa to 0.5 MPa is preferable. An optimum projection condition may be selected by combining conditions such as the particle diameter of the abrasive particles, the moving speed of the blast gun or the substrate, the number of times of blasting, that is, the blast projection time, with the pressure in this range. Note that the nozzle shape at this time has a small blast projection range and needs to be moved within the substrate surface, so that the processing takes time, so the efficiency is low, and unevenness tends to occur. Therefore, it is not spot-like (dot-like) such as 2 mmφ or 5 × 5 mm, but is relatively wide, for example, 2 mm × 90 mm or 2 mm × 200 mm (or 300 mm, 600 mm). It is preferable that a wide area can be processed at a time by moving the nozzle and / or the substrate. In addition, if the width that can be processed determined by the nozzle shape is smaller than the width of the substrate to be processed, the overlapping portions of the processing are likely to be uneven. This is more preferable because the entire surface of the substrate can be processed by the relative movement of the rotation.
[0053]
In addition, although water is illustrated as a liquid in said example, it is not limited to this. It is also possible to use chemical polishing of the constraining sheet using various solvents and chemicals as liquids, remove organic components adhering to the substrate surface, and activate the substrate surface. Similarly, the gas is not limited to air, and a gas such as nitrogen or argon can also be used.
[0054]
Thus, the method of projecting a mixture of liquid, abrasive particles, and gas results in soft polishing as compared with dry blasting such as sandblasting that directly projects only abrasive particles. This is because in dry blasting, fine abrasive particles become dust and cannot be effectively projected, so the abrasive particles must have a large particle size, resulting in glass ceramic substrates and metallized conductors. In the wet blast which is an example of the method in the present invention, the slurry, which is a mixture of liquid and abrasive particles, is accelerated by air pressure, while the damage to the surface tends to increase and the surface roughness tends to increase. This is because, since these mixtures are projected, the liquid is atomized to provide an appropriate buffering action.
[0055]
On the other hand, in wet blasting such as jet scrub that projects a mixture of liquid and abrasive particles, the water flow hits the treated surface, which acts as a puddle and acts as a cushion, weakening the processing force to compensate for this. In addition, it is necessary to enlarge the abrasive particles, but this tends to increase the surface roughness of the treated surface. Further, since it is necessary to directly project a mixture (slurry) of abrasive particles and water at a high pump pressure, the damage on the slurry piping is increased, and the apparatus needs to be frequently maintained. On the other hand, the method of projecting a mixture of liquid, abrasive particles and gas in the present invention is advantageous in that such a problem is unlikely to occur and good processing can be performed.
[0056]
In the obtained multilayer glass ceramic substrate, shrinkage during firing is restrained only in the thickness direction by the constraining green sheet, so that shrinkage in the laminated surface can be suppressed to about 0.5% or less, and glass Since the ceramic green sheet is uniformly and reliably bonded to the entire surface by the constraining green sheet, it is possible to prevent warping and deformation from occurring due to partial peeling of the constraining green sheet.
[0057]
【Example】
EXAMPLES Hereinafter, although an Example and a comparative example are given and the method of this invention is demonstrated in detail, this invention is not limited only to the following Examples.
[0058]
Example 1
As a glass ceramic component, SiO₂-Al₂O_Three-MgO-B₂O_Three-ZnO-based glass powder 60% by weight, CaZrO_Three20% by weight of powder, SrTiO_Three17% by weight of powder and Al₂O_Three3% by weight of powder was used. To 100 parts by weight of this glass ceramic component, 12 parts by weight of an acrylic resin as an organic binder, 6 parts by weight of a phthalic acid plasticizer and 30 parts by weight of toluene as a solvent were added and mixed by a ball mill method to form a slurry. Using this slurry, a glass ceramic green sheet having a thickness of 300 μm was formed by a doctor blade method.
[0059]
Next, a conductor pattern was formed on the green sheet by screen printing using a silver-palladium paste. As the conductor paste, 100 parts by weight of an alloy powder (average particle size: 1.0 μm) with a weight ratio of Ag: Pd of 85:15 is Al.₂O_ThreeA mixture of 2 parts by weight of powder and 2 parts by weight of glass powder having the same composition as that of the glass, a predetermined amount of ethyl cellulose resin and terpineol as vehicle components, and mixed to have an appropriate viscosity by three rolls was used.
[0060]
On the other hand, Al as an inorganic component₂O_ThreeUsing the powder, a slurry was prepared in the same manner as the glass ceramic green sheet, and then molded to obtain a constrained green sheet having a thickness of 250 μm.
[0061]
The adhesive is made of SiO with a softening point of 720 ° C.₂-Al₂O_Three-MgO-B₂O_ThreeA mixture of 25% by weight of ZnO glass powder, 39% by weight of DBP, 31.2% by weight of BCA, and 4.8% by weight of an acrylic binder was used.
[0062]
A glass ceramic / green sheet laminate is obtained by stacking a predetermined number of glass ceramic / green sheets with a conductor pattern formed on the surface. A laminate was obtained by pressure bonding.
[0063]
The obtained laminate was placed on an alumina setter, heated at 500 ° C. in air for 2 hours to remove organic components, and then fired at 900 ° C. for 1 hour. After firing, constraining sheets were attached to both surfaces of the glass ceramic substrate. In this state, the restraint sheet did not peel off even when tapped lightly.
[0064]
The constraining sheet attached to the surface of the glass-ceramic substrate is spherical Al with an average particle size of 25 μm.₂O_ThreeThe powder was removed by wet blasting using abrasive particles. At this time, the slurry is a mixture of water and abrasive particles, and the concentration of the abrasive particles in the slurry is 20% by volume, the blast air pressure is 0.15 MPa, and the moving speed of the substrate is 5 mm / s. , Washed with water.
[0065]
The surface of the glass ceramic substrate after removing the constraining sheet was a smooth surface having a surface roughness Rz of less than 5 μm. The metallized surface was also smooth with a surface roughness Rmax of less than 5 μm, and when the metallized state was evaluated by wire bonding and solder wettability of an aluminum wire having a diameter of 200 μm, there was no problem at all.
[0066]
Further, the shrinkage in the laminated surface of the obtained glass ceramic substrate was 0.5% or less, and no warpage or deformation was observed in the substrate.
[0067]
(Example 2 and Example 3)
A glass-ceramic substrate was obtained in the same manner as in Example 1 except that an adhesive was prepared using glasses having a softening point of 600 ° C and 700 ° C, respectively.
[0068]
(Comparative Example 1)
A glass ceramic substrate was obtained in the same manner as in Example 1 except that an adhesive containing no glass was prepared.
[0069]
(Comparative Example 2)
A glass ceramic substrate was obtained in the same manner as in Example 1 except that an adhesive was produced using glass having a softening point of 920 ° C.
[0070]
(Comparative Example 3)
A glass ceramic substrate was obtained in the same manner as in Example 1 except that an adhesive was prepared using glass having a softening point of 400 ° C.
[0071]
As a result, the glass ceramic substrates obtained in Example 2 and Example 3 had a shrinkage within the laminated surface of 0.5% or less (that is, a shrinkage rate of 99.5% or more), as in Example 1, and warped the substrate. No deformation was observed.
[0072]
On the other hand, the glass ceramic substrates obtained in Comparative Example 1 and Comparative Example 2 do not contain glass, or contain glass having a softening point higher than the firing temperature. In either case, the constrained green sheet was easily peeled off from the fired glass ceramic substrate. Also, since the bonding force between the glass ceramic green sheet and the constraining green sheet is weak, the shrinkage rate within the laminated surface of the glass ceramic substrate is about 85%, or only part of the substrate is bonded to the constraining sheet. As a result, the glass ceramic substrate was greatly deformed.
[0073]
On the other hand, in Comparative Example 3, since the softening point of the glass contained in the adhesive layer is low, the organic component is not completely removed. Therefore, the shrinkage within the laminated surface of the glass ceramic substrate is as good as 0.5% or less. However, the color tone of the glass ceramic substrate turned gray.
[0074]
(Examples 4 to 7)
As a glass ceramic component, SiO₂-MgO-CaO-Al₂O_Three-Based glass powder 70% by weight, Al₂O_Three30% by weight of powder was used. To 100 parts by weight of the glass ceramic component, 9.0 parts by weight of an acrylic resin as an organic binder, 4.5 parts by weight of a phthalic plasticizer, and 30 parts by weight of toluene as a solvent were added and mixed by a ball mill method to form a slurry. Using this slurry, a glass ceramic green sheet having a thickness of 300 μm was formed by a doctor blade method.
[0075]
Next, a conductor pattern was formed on the green sheet by screen printing using the same silver-palladium paste as in Example 1.
[0076]
The same restraint green sheet as in Example 1 was prepared.
[0077]
On the other hand, the adhesive is SiO having a softening point of 720 ° C.₂-MgO-CaO-Al₂O_ThreeThis was prepared using a mixture of a glass powder, DBP, BCA, and an acrylic binder in the proportions shown in Table 1.
[0078]
A glass ceramic / green sheet laminate is obtained by stacking a predetermined number of glass ceramic / green sheets having a conductor pattern formed on the surface, and an adhesive layer is coated on both surfaces of the laminate by screen printing on the surface to be adhered to the laminate. The constrained green sheets formed with were laminated and pressure-bonded at a temperature of 55 ° C. and a pressure of 20 MPa to obtain a laminate.
[0079]
The obtained laminate was placed on an alumina setter, heated at 500 ° C. in the atmosphere for 2 hours to remove organic components, and then fired at 850 ° C. for 1 hour. Subsequently, the restraint sheet adhering to the surface of the glass ceramic substrate was removed in the same manner as in Example 1. Examples 4 and 5 were performed under the conditions of a blast air pressure of 0.1 MPa and a treatment frequency of 3 times. The surface of the obtained glass ceramic substrate was a smooth surface having a surface ancestor Rz of 5 μm or less, and there was no problem with the solder wettability of the conductor.
[0080]
In addition, Table 1 shows the shrinkage ratio in the laminated surface of the obtained glass ceramic substrate. Note that no warpage or deformation was observed in the glass ceramic substrate.
[0081]
[Table 1]

[0082]
From Table 1, it can be seen that the glass ceramic substrates obtained by using the adhesives of Examples 4 to 7 have high dimensional accuracy because the shrinkage during firing is suppressed. In addition, in the results shown in Table 1, warpage is obtained by measuring the height of warpage using a laser optical non-contact three-dimensional shape measuring apparatus.
[0083]
(Example 8)
A glass ceramic substrate was obtained in the same manner as in Example 7 except that the abrasive particles were changed to glass beads (spherical glass powder) having an average particle size of 30 μm. As a result, a good substrate similar to that of Example 7 was obtained.
Example 9
A glass ceramic substrate was obtained in the same manner as in Example 5 except that the abrasive particles were changed to an average particle size of 50 μm and the blast air pressure was changed to 0.1 MPa. A good substrate similar to that of Example 5 was obtained.
(Comparative Example 4)
A glass ceramic substrate was obtained in the same manner as in Example 5 except that the abrasive particles were changed to urea resin having an average particle diameter of 100 μm. The restraint sheet could be removed by increasing the blast air pressure.
[0084]
(Comparative Examples 5-7)
A glass ceramic substrate was obtained in the same manner as in Example 7 except that the average particle size of the abrasive was changed to 100 μm, 75 μm and 3 μm.
[0085]
When the average particle size is 100 μm, the metallized conductor may be partially peeled off. This is because the abrasive power increases because the particle size and mass of the abrasive particles increase. Note that it was possible to achieve a practical balance between removal of the restraining sheet and peeling of the metallized conductor by lowering the blast air pressure.
[0086]
When the average particle size was 75 μm, the restraint sheet could be removed almost completely when the blast air pressure was 0.1 MPa. In this case, the surface roughness Rmax of the metallized conductor surface was about 5 μm, and when the metallized surface was observed, a slightly large depression was observed. This is considered to be a trace of the abrasive particles having a relatively large particle size hitting the metallized surface.
When the average particle size was 3 μm, sufficient removal was somewhat difficult in a short time. When the blast air pressure is increased, the removability is improved. However, since the pressure is high, damage to the metallized conductor tends to increase, and the metallized conductor partially swells. In addition, the removal of the restraint sheet in a favorable surface state was possible by extending the treatment time.
[0087]
(Comparative Example 8)
A glass ceramic substrate was obtained in the same manner as in Example 5 except that the abrasive particles were changed to non-spherical polygonal abrasive particles. In this case, when the surface of the metallized conductor was observed, the attached restraint sheet was removed, but there were cases where abrasive particles remained stuck on the metallized conductor. In addition, by appropriately adjusting the processing conditions, it was possible to remove the constraining sheet in a good surface state.
[0088]
【The invention's effect】
According to the present invention, a constrained green sheet that is bonded to both sides of a glass ceramic / green sheet laminate through an adhesive layer containing glass that acts as a binder during firing and does not substantially shrink during firing. Since the glass is laminated and fired, shrinkage within the laminated surface of the glass ceramic green sheet substrate can be reliably suppressed, and the fired restraint sheet and adhesive layer are projected with a mixture of liquid, abrasive particles, and gas. Therefore, there is an effect that a glass ceramic substrate having a good surface state with high dimensional accuracy can be obtained which is free from warping and deformation, and has no adhesion residue of the constraining sheet or damage to the substrate surface.

Claims (6)

A step of laminating a plurality of glass ceramic green sheets containing an organic binder and having a conductor pattern formed on the surface thereof to produce a glass ceramic green sheet laminate;
Applying an adhesive containing glass and a solvent to a constrained green sheet containing a hardly sinterable inorganic material and an organic binder;
The applied adhesive layer is provided between the constrained green sheet and the glass ceramic / green sheet laminate on both surfaces of the glass ceramic / green sheet laminate, and the constrained green sheet coated with the adhesive is laminated. And a process of
Removing the organic component from the laminate of the constrained green sheet and the glass ceramic green sheet laminate, and then firing to produce a glass ceramic substrate holding the restraint sheet;
Projecting a mixture of liquid, abrasive particles and gas onto the constraining sheet to remove the constraining sheet from the glass ceramic substrate,
The glass content in the adhesion agent, Ri amount der to be removed the constraining green sheet during firing from glass-ceramic substrate with constraining sheet after coupled to form and firing the glass ceramic green sheet, contained in the adhesion agent the softening point of the glass is, the manufacturing method of a glass ceramic substrate, characterized in der Rukoto firing temperature below the glass ceramic green sheet laminate. The softening point of the glass contained in the adhesion agent, process for producing a glass ceramic substrate of the high claim 1 Symbol placement than the volatilization temperature of the organic component. The glass content in the adhesion agent, process for producing a glass ceramic substrate according to claim 1, wherein from 5 to 50% by weight of the adhesion Ingredient.   The method for producing a glass ceramic substrate according to claim 1, wherein the thickness of the constraining green sheet is 10% or more with respect to the thickness of the glass ceramic / green sheet laminate on one side.   The method for producing a glass ceramic substrate according to claim 1, wherein the method of projecting a mixture of the liquid, abrasive particles and gas is wet blasting. Process for producing a glass ceramic substrate of the abrasive particles are spherical inorganic powder having an average particle size of 5~50μm claim 1 or claim 5, wherein.