DE4103778C1 - - Google Patents

Description

The invention relates to a sintered glass ceramic with hexagonal cordierite glass powder crystallizable as the main crystal phase.

Suitable due to its good mechanical and electrical properties Cordierite is a very good substrate for electronic components, in particular for multilayer printed circuit boards. Because pure cordierite has very high sintering temperatures owns, where those applied before sintering Conductor tracks are destroyed, one assumes glass powder, which is proportionate low temperatures can be sintered and thereby largely converted into a crystal phase at the same time.

It is known that glass powder, the composition of which is stoichiometrically pure Corresponds to cordierite, are only sinterable to a very limited extent. By pressing and firing at temperatures up to 1200 ° C produces porous and mechanical little solid sintered glass ceramics. The poor sinterability is due on premature surface crystallization of the glass particles, causing a dramatic increase in viscosity over several powers of ten comes, which prevents further sintering of the glass phase. It is also disadvantageous that MgO-containing high quartz mixed crystal Train phases. Representatives from this mixed crystal series are the µ-cordierite with a ratio of the oxides MgO to Al₂O₃ to SiO₂ of 2: 2: 5 and a magnesium aluminosilicate (MAS) with a ratio of 1: 1: 4. The existence of these metastable crystal phases delays the Crystallization to hexagonal cordierite in addition. Such a glass powder, the magnesium aluminum silicate as a secondary crystalline phase contains is described in DE 37 01 973 A1.  

Glass powder with a modified composition is also known, where the sinterability is improved. According to US Pat. No. 3,926,648 the sinterability by adding 0.5-2 wt .-% K₂O and / or Cs₂O improved. The sintered bodies made from these glass powders have however, deteriorated electrical and dielectric properties, so that their application for electrotechnical and electronic components, in particular for high requirements, generally prohibited. In DE-PS 26 02 429 this modification is carried out by adding 0.7-5.6 mol% of one or more of the modifying oxides BaO, PbO, SrO or CaO. These oxides are able to form mixed crystals in the cordierite structure. As a result however, the small proportion of residual glass phase is the sinterability of the powder so that the powders are their main uses find as coatings on objects made of ceramic, glass or glass ceramic. DE-PS 29 01 172 describes two different sintered glass ceramics, glass ceramics based on β-spodumene as the most important crystalline phase and secondly a sintered glass ceramic on the Base of cordierite as the most important crystalline phase. The structure of the the latter sintered glass ceramic contains in addition to the hexagonal cordierite still clinoenstatite and occasionally µ-cordierite. This complex The structure requires all process parameters such as chemical Composition, powder properties and sintering program in tight tolerances to maintain a constant structure and thus reproducible To achieve properties. These sintered glass ceramics are essential therefore a lot of effort in production and they are difficult to find adapt to different processing conditions of different users. In US-PS 45 40 671 is sinterable to a sintered glass ceramic Glass powder described in the cordierite in the sintered state and a high quartz mixed crystal phase in solid solution. The Occurrence of the metastable high quartz mixed crystal phase leads to the disadvantages already described. EP 02 89 903 A1 describes a Coating mass for nickel and for iron-based alloys described in addition to cordierite, other magnesium aluminum silicates, especially sapphirine (4 MgO-5 Al₂O₃-2 SiO₂) contains. This coating mass must be at temperatures Branded on the body to be coated from 1140 ° C-1300 ° C will.

The object of the invention is to form a sintered glass ceramic Glass powder crystallizable with hexagonal cordierite as the main crystal phase to find that is composed so that it is at temperatures of 970 ° C and below hermetically sintered, good electrical and mechanical  Possesses properties and the user when choosing the sintering conditions a large margin in terms of heating speed, Sintering temperature and sintering time.

This object is achieved by the glass powder described in claim 1 solved.

To obtain a dense sintered glass ceramic, i.e. H. without open pores, with a large proportion of crystal phases, is the sintering and crystallization process important. In contrast to a compact glass ceramic, which is due to clogged Nucleating agents such as titanium dioxide or zirconium dioxide Experiencing volume nucleation in the interior goes into making one Sintered glass ceramic made of glass powder crystallized from the former Surfaces of the particles of the glass powder. The sealing sinter must largely carried out in the glassy state. If there is premature Surface crystallization, the viscosity of the surface layer increases the glass particles so strongly that the further sealing sintering strongly hinders if not interrupted at all. If you suppress it Crystallization ability of the glass z. B. by larger additions to modifying Oxides can be the desired homogeneous, fine crystalline No longer manufacture structures with a high proportion of crystal phases. Arise then coarsely crystalline sintered glass ceramics with low strength, which for most applications are unsuitable.

The SiO₂ content in the glass powder should be between 48-61 mol%. Sinks the SiO₂ content below 48 mol%, sintering is sufficient Crystallization of hexagonal cordierite phase not possible below 970 ° C. If the SiO₂ content exceeds 61 mol%, crystallize preferentially metastable magnesium aluminosilicate crystals with the ones described at the beginning Disadvantages. An SiO₂ content between 51 and 57 mole%. The Al₂O₃ content is between 10 and 16 mol%. Will the ceiling exceeded by 16 mol%, so the temperature increases, which is used to manufacture a densely sintered sintered glass ceramic is required, while falling below an Al₂O₃ content of 10 mol% of Crystal phase portion of the desired hexagonal cordierite phase decreases and reinforced MgO- and SiO₂-containing crystal phases are formed, which too  lead to an increase in the dielectric constant. A salary is preferred from 12.5-15.5 mol% Al₂O₃. The MgO content is said to be between 23 and 35 Mol%. Exceeding this range leads to a reduced one Share of hexagonal cordierite while falling below this range deterioration in the sintering properties of the glass powder leads. A content of 26-31 mol% of MgO is preferred.

To lower the sintering temperature, the glass powder contains up to 4 mol% B₂O₃ and up to 2.5 mol% P₂O₅, the total content of this both compounds are between 0.5 and 5 mol%. The upper limits of this Areas should not be exceeded, otherwise the residual glass phase takes over, which leads to a deterioration in properties. As Contribution to lowering the sintering temperature should, however, the addition of B₂O₃ and / or P₂O₅ in total not less than 0.5 mol%.

Zinc oxide additives promote the crystallization of the hexagonal cordierite low temperatures. However, the zinc oxide content should not exceed 3 mol%, otherwise there is a risk that due to premature Surface crystallization the sintering to a dense body extraordinarily is difficult. A zinc oxide content of 0.3 to is preferred 2.5 mol%. CaO contents also promote crystallization low temperatures, but contents above 3 mol% should be avoided, because at such low levels, anorthite is additional and undesirable Crystal phase occurs. BaO additives improve homogeneity and stability in the melting of glass. However a BaO of 1.5 mol% should not be exceeded, since the crystallization at higher contents of the glass powder inhibited and at impermissibly high temperatures is moved.

An essential element of the invention is a fluorine content of 0.5- 12 mol%, preferably from 0.5-11 mol%, the fluorine ion being a corresponding one Amount of oxygen ions replaced in the crystal lattice. Could be surprising be found that the crystallization temperature by adding fluorine of the glass powder to lower temperatures below 900 ° C leaves without the sintering process being adversely affected. This Behavior is in contrast to the crystallization-promoting additives  like zinc oxide or barium oxide, where there is always a compromise between Sealing internally and lower crystallization temperature can be closed got to. The addition of fluorine promotes the crystallization of the hexagonal Phases and suppresses the undesired precursor phases µ-cordierite and magnesium aluminosilicate. The structure remains over a wide temperature range stable for sintering and crystallization. The content of Fluorine should not exceed 12 mol%, otherwise new fluorine-containing crystal phases can occur, reducing the stability of the structure against changes the sintering temperature is adversely affected. Further the homogeneity of the glass melt and the hydrolytic also deteriorate Resistance of the sintered glass ceramic. Even small additions of Fluorine significantly lowers the crystallization temperature while lowering or reducing the sintering temperature sintering times, however, the fluorine content should not fall below 0.5 mol% as the effects of the addition of fluorine are not always included is satisfactory.

As a further crystallization-promoting additive, PbO, SrO or SnO₂ can be added will. The maximum amount of each oxide should not be 3 mole% exceed. If several of these three oxides are used together, the total amount used should also not exceed 3 mol% lie. Additions higher than 3 mol% lead to premature crystallization, so that good sintering is prevented. When using PbO must also ensure that at higher sintering temperatures in reducing sintering atmosphere reduces the lead oxide to metallic lead can become, which leads to an impermissible reduction in the electrical volume resistance leads.

In the manufacture of the glass from which the glass powder is made, can usual refining agents such. B. Sb₂O₃, As₂O₃ or cerium compounds in the usual concentrations of up to about 1 wt .-% added to the glass without negatively affecting its properties. However, it is not absolutely necessary.

The grain size of the sinterable glass powder plays a major role for the optimization of sintering and subsequent surface crystallization.  In general, glass powder with an average grain size is used between 1 and 12 µ good results. If the grain sizes are too small, this tends to Glass powder due to the large surface / volume ratio too early Surface crystallization, which prevents good sintering becomes. Grain sizes that are too large in turn complicate later crystallization, as they deteriorate to a relatively coarse crystalline structure lead mechanical strength and sintered body with increased surface roughness surrender. You get particularly favorable results with an average grain size of the glass powder between 1.5 and 7 microns.

The glass powders are produced in a manner known per se so that usual glass raw materials a glass of the composition described Temperatures of around 1450-1650 ° C are melted, the melted glass then quenched by pouring it into cold water or on chilled metal rollers and results in a glass break that is known to Frit production or grinding process for powders of the described Grain size is processed.

The glass powder thus obtained is then in a manner known per se, for. B. with the molding processes commonly used in the ceramics industry, such as dry pressing, Extrusion, injection molding, film drawing, etc. into a shaped body processed. The processing is carried out with the addition of customary market organic auxiliaries and / or suitable suspending agents. So you go e.g. B. in the extrusion of a plasticized mass with plastic properties out. The dry pressing is carried out by adding pressing aids and processing into free-flowing press granules. For the Manufacture of flexible green foils, from which later electronic substrates are produced, the film has been drawn from a ceramic Proven slip. When adding suspending agents is before sintering another drying process required. Possibly existing organic Auxiliaries are added during the heating process by means of a suitable temperature control of the sintering program burned out before a noticeable Sintering of the glass takes place. Sintering and crystallization of the Glass powder takes place depending on the composition of the glass powder at temperatures between about 850-970 ° C. The required sintering times depend on the sintering temperature used and are between about 15 minutes and  several hours. Lower sintering temperatures require an extension the sintering period. With a given glass composition, if necessary, at a desired low sintering temperature by extending the sintering time, a structure similar to that is obtained this is also available with a high sintering temperature and a short sintering time would. A pore-free sintered glass ceramic is produced therefore in such a way that a glass of the composition described is produced, crushed this glass to a particle size of 1-12 µm, the glass particles into the desired shape, which are brought into shape Glass particles continuously heated up to a temperature of up to 970 ° C and hold at that temperature until the particles sinter together and that Glass is devitrified and then the sintered objects are cooled. In front the shaped bodies or precursors thereof can be heated and sintered with patterns of electrical cables, e.g. B. by screen printing or the like be provided.

Although the composition of the glass powder according to the invention of the stoichiometric The composition of the cordierite deviates due to mixed crystal formation nevertheless high crystal phase proportions with hexagonal Cordierite structure produced, whereby crystal phases not consisting of cordierite or the residual glass phase can be kept relatively small. This mixed crystal formation still allows the installation of superstoichiometric amounts of MgO and SiO₂ at the expense of Al₂O₃ without the crystallinity worsened. However, the sinterability of the glass powder is improved and reduces the amount of modifying oxides required.

The sintered glass ceramics produced from the glass powder according to the invention are hermetically sealed and therefore allow the encapsulation to be more sensitive electronic components. Because of the low dielectric constant electronic substrates with metallization made therefrom have little Signal delay delays. The low sintering temperature of a maximum of 970 ° C allows metallizations from highly conductive metals such as copper, silver, silver-palladium and gold. The coefficient of thermal expansion the sintered glass ceramic can be adapted to that of silicon, so that mechanical tension between substrate material and Silicon semiconductor wafers due to different coefficients of thermal expansion  be minimized. In addition to compact sintered glass ceramic substrates are also multi-layer wiring substrates with internal ones Conductor tracks possible. Made from the glass powder according to the invention Sintered glass ceramics are characterized by low heat conduction, high temperature resistance and good thermal shock behavior. The height electrical volume resistance and the high dielectric strength allow use for electrical insulation purposes. The glass powder are also suitable for coating or joining ceramics and are stable even at high temperatures.

The invention is further illustrated by the examples. The results are summarized in Tables 1-4. In Tables 1 and 3 are the chemical composition, in Tables 2 and 4 physical data of the examples given. The middle of the physical data Grain size (d₅₀) measured using a laser granulometer. The sintering was carried out at the specified temperatures, with a uniform Heating rate of 3 ° C / min. was used. For the determination The following X-ray reflections were used for the crystal phase contents: 102 reflex for hexagonal cordierite; 011 reflex for MAS; 120-reflex for forsterite; 610-Reflex for magnesium aluminosilicate (JCPDS 35-310). Occasionally occurred Low levels of entatite modifications in the sintered glass ceramics on. Because of the large number of possible modifications and the small number A qualitative estimate had to be made here. The Determination of the hexagonal cordierite (JCPDS file number 13-293), µ-cordierite (JCPDS file number 14-249) and forsterite (JCPDS file number 34-189) against fully crystallized standards. The comparison standard for the MAS phase (JCPDS 27-716) also contained other crystal phases, see above that the quantities given here with a somewhat larger error (order of magnitude approx. 20%) are affected. The dielectric constant ε and the loss angle Tan δ were measured at 25 ° C and a frequency of 1 MHz. At higher frequencies in the Giga-Hertz range, the electricity constant decrease and loss angle significantly. To estimate the crystallization temperatures differential thermal analysis was used. Since the Differential thermal analysis method-related with high heating rates (here 5 ° C / min.), the real crystallization temperature is systematically deeper with normal sintering programs. A statement about the  Influence of the chemical composition on the crystallization temperature is however possible. The beginning of the Crystallization peaks and the crystallization maximum specified. These Values allow the crystallization temperatures of various sintered glass ceramics relative to each other.

Examples 1-4 (Tables 1 and 2) show the influence of the fluorine content on sintering temperature and crystallization behavior with otherwise the same composition. Example 1 is used for comparison. The glass powder with The compositions given in Table 1 were made by Melt a corresponding batch at 1600 ° C. The melt was quenched between two water-cooled metal rollers and onto the ground grain size specified in Table 2. The glass powder became one Free-flowing press granules obtained in which the powder in an intensive mixer with an aqueous solution of polyethylene glycol in known per se Way is granulated. By dry pressing under a pressure of Shaped bodies for the sintering tests were produced at 800 bar. The sintering period is 1 hour at the specified sintering temperature, the heating up time is 3 ° C / min. A stop of 1 hour was carried out at a temperature of 310 ° C. inserted to remove the polyethylene glycol from the sintered body.

Examples 2-4 show very clearly in comparison to Example 1 extremely positive influence that the fluorine content exerts. From table 2 it can be seen that fluorine lowers the crystallization temperature Shifts temperatures. The crystallization of hexagonal cordierite is promoted, the other crystal phases are suppressed. The The structure is stabilized, the crystal phase proportion changes in one wide temperature range only a little, in example 3 the content of hexagonal cordierite at sintering temperatures between 910 and 970 ° C almost constant. As a result of the stabilization of the structure due to the fluorine content also the coefficient of thermal expansion for the compositions according to the invention only slightly changed at sintering temperatures between 910 and 970 ° C. Example 1, which was produced for comparison without fluorine, on the other hand shows strongly fluctuating crystal phase contents and a different one Coefficient of thermal expansion. All sintered bodies according to the invention  are hermetically sealed at the specified sintering temperatures sintered.

Examples 5-13 with further glass powder compositions according to the invention are summarized in Tables 3 and 4. The examples show 11-13 the influence of the crystallization-promoting additives SrO, PbO and SnO₂.

Example 14

From the glass powder according to Example 8, flexible green films with a Thickness of 200 microns produced by the following procedure. The glass powder was in a ball mill with organic tools and an organic Solvent mixture added, homogenized and to a pourable Slurry processed. The batch consisted of 53% by weight of glass powder, 37 % By weight of an acetropic solvent mixture of trichlorethylene and Ethanol, 5% by weight polyvinyl butyral as binder, 4% by weight dioctyl phthalate as Plasticizer and 1% by weight Menhaden fish oil as a plasticizer. The Slurry was vented and poured onto a moving endless belt. Between Casting shoe and band is a narrow adjustable gap, which controls the thickness of the foils. After passing through a drying section the flexible film can be removed from the casting belt.

Several layers of these green sheets were stacked on top of one another and in one Laminating press at a pressure of 0.5-3 kN / cm² and a temperature of 90 ° C pressed into a uniform composite. The laminates thus obtained were on a flat firing surface at a temperature of 930 ° C and a sintering time of 1 hour. Because of the higher levels of organic Aids were generally at a heating rate of 2 ° C / min. worked. Near the burnout temperature, i.e. H. in the temperature range from 220 ° C to 330 ° C, the heating rate was up 1 ° C / min. decreased. The laminates were then held at 330 ° C for two hours treated to complete the removal of the organic aids. Then again at 2 ° C / min. until the desired one is reached  Sintering temperature heated. Structure and properties of the so obtained Sintered glass ceramic substrates agree with the values that also apply to Sintering compacts can be obtained with the same temperature program.

The specific electrical volume resistance was included in all examples Room temperature higher than 10¹³ · Ω cm, d. that is, a very good electric insulating material is present.  

Table 1

Glass powder compositions (mol%)

Table 3

Glass powder compositions (mol%)

Claims (4)

1. To a sintered glass ceramic with hexagonal cordierite as the main crystal phase, crystallizable glass powder, characterized by a composition in mol% on an oxide basis of 48-61 SiO₂,
10-16 Al₂O₃,
23-35 MgO,
0-4 B₂O₃,
0-2.5 P₂O₅,
0.5-5 Σ B₂O₃ + P₂O₅,
0-3 ZnO,
0-3 CaO,
0-1.5 BaO,
0.5-12 F in exchange for O. 2. Glass powder according to claim 1, characterized by a composition of 51-57 SiO₂,
12.5-15.5 Al₂O₃,
26-31 MgO,
0.5-2.5 P₂O₅,
0.3-2.0 B₂O₃,
1.0-3.0 Σ P₂O₅ + B₂O₃,
0.3-2.5 ZnO,
0.5-11.0 F in exchange for O. 3. glass powder according to claims 1 or 2, marked by a total content of up to 3 mol% of one or more of the Oxides PbO, SrO, SnO₂. 4. glass powder according to at least one of claims 1 to 3, marked by an average grain size of 1 to 12 µm.