Title of Invention

METHOD FOR PREPARING A POROUS CERAMIC MATERIAL WITH HIGH HEAT RESISTANCE

Abstract The present invention relates to a method for preparing a porous ceramic material, particularly for thermal insulation, comprising the steps of providing a first composition in the form of a stable aqueous colloidal solution of silica and oxides of alkaline metals; providing a second stable composition in the form of a suspension in an organic liquid of inorganic and/or organic particles, the second composition containing compounds which, when the second composition is mixed with the first composition, can destabilize the first composition, forming gel, and can form an organic polymeric net together with a blowing agent; mixing the first composition and the second composition to form a mixture; forming from the mixture a porous structure in gel form, where an organic structure supports inorganic structures being formed; solidifying the porous structure in gel form, obtaining a porous ceramic material in which an organic polymeric net surrounds inorganic portions.
Full Text METHOD FOR PREPARING A POROUS CERAMIC MATERIAL WITH
HIGH HEAT RESISTANCE
Technical Field
The present invention relates to a method for preparing porous
ceramic materials of the type with high heat resistance, for high heat
insulation, in particular for industrial applications as insulating parts for
high-temperature processes, having even complex shapes obtained by
extrusion or injection molding.
Background Art
It is known to prepare a body constituted by a porous material by
mixing powders or granulates of materials of the ceramic type, generally
A12O3, SiO2, TiO2, ZrO2, CSi, TiC, NSi and alkaline oxides such as Na2O,
K2O, with a binder selected among organic materials such as acetic acid,
sodium acetate, zinc acetate, propionic acid [1]. The process entails a
reaction of the particles of metallic oxides with the binder, at a temperature
below the sintering temperature at which the mixture is subjected to fire and
drying.
A method is also known [2] for preparing a sintered porous body
made of ceramic and/or metallic materials, which includes the mixing of an
aqueous suspension containing powders of ceramic or metallic materials and
of a binding resin (binder) which is a water-soluble polymer which can gel,
and a blowing ajgent which activates the porosity of the gel, which becomes
expanded; as the temperature increases, a porous metallic-ceramic material
is formed by drying and sintering and its polymeric part is eliminated by
pyrolization.
Another known method for preparing porous ceramic materials
includes mixing ceramic powders with solid or hollow plastic pellets [4], [5]
in a liquid in order to obtain a suspension, followed by drying and treatment
in a high-temperature oven in an oxygen-free environment so that the plastic
pellets that first act as adhesive for the ceramic powders are eliminated by

pyrolysis, forming porosities.
It is also known that silica gels dissociate in the presence of water and
alkaline metal hydroxides and can be destabilized further by other
components, such as for example organic components known as
electrolytes, which convert silica sol into gel by means of a phase transition
depending on the degree of alkalinity of the aqueous suspension of silica,
generating gel systems of a different kind [3], A particular type of gel forms
when the destabilization process of a colloidal solution of silica and alkaline
compounds is activated by neutral reagents or acids, for example organic or
mineral acids, esters and salts
Known processes for obtaining porous ceramic materials with high
heat resistance generally entail a technology which is highly advanced from
an engineering standpoint and very complicated and laborious to obtain
refractory articles having a particular shape.
Moreover, in known processes, particularly advanced and
sophisticated technologies which are not convenient in terms of production
costs are applied to obtain large amounts of material in the industrial field.
Disclosure of the Invention
The aim of the present invention is to provide a method for preparing
a porous ceramic material which is simple, inexpensive, and easy to use
industrially and has a performance which can be compared with known
more sophisticated and technologically advanced porous ceramic materials.
An object of the present invention is also to provide a process for
preparing a porous ceramic material which takes into account environmental
and workplace hygiene aspects, porous ceramic materials which can be used
instead of traditional materials such as mineral fibers, which are potentially
pathogenic for the respiratory tract, for example due to the micrometer-size
dust spread in the atmosphere during processing, and due to their skin
irritation power, and also have difficulties in the disposal of the associated
waste.

Another object of the present invention is to provide a method for
preparing a porous ceramic material which allows to fill even cavities and
interspaces having a very complex shape without forming, over time, even
in conditions of vibration or displacement caused by thermal expansions,
dust or voids and discontinuities of the material between the interspaces.
Another object of the present invention is to provide a method for
preparing porous ceramic material which has no negative effects on human
health.
Another object of the present invention is to provide a method for
producing a porous ceramic material which allows complete recyclability of
the material and the use of production residues for other applications, for
example as absorbent powders for industrial oil spills and as additive for
producing flameproof glass.
Another object of the present invention is to provide a method for
preparing a porous ceramic material in a homogeneous form with good
resistance to mechanical stresses.
Another object of the present invention is to provide a method for
preparing a porous ceramic material which can be used as absorbent powder
in case of industrial oil spills, as additive for the production of flameproof
glass, and as a material having piezoelectric properties.
Still another object of the present invention is to provide a method for
preparing a porous ceramic material for use in multilayer materials, in the
form of profiles, sheets, bars, and can be worked with manual tools and
machine tools
This aim and these and other objects which will become better
apparent from the following detailed description of the invention are
achieved by the method for preparing a porous ceramic material, particularly
for thermal insulation, comprising the steps of:
-providing a first composition in the form of a stable aqueous
colloidal solution of silica and oxides of alkaline metals;

- providing a second stable composition in the form of a suspension
in an organic liquid of inorganic and/or organic particles, said second
composition containing compounds which, when the second composition is
mixed with said first composition, can destabilize said first composition,
forming gel, and can form an organic polymeric mesh together with a
blowing agent;
- mixing said first composition and said second composition to form a
mixture;
- forming from said mixture a porous structure in gel form, where an
organic structure supports inorganic structures being formed;
- solidifying said porous structure in gel form, obtaining a porous
ceramic material in which an organic polymeric net surrounds inorganic
parts.
The method according to the present invention can further comprise
the step of:
- introducing the formed gel, before solidification, in a mold, an
interspace or a cavity by injection or extrusion, followed by
- solidifying the gel in situ in said mold, interspace or cavity,
obtaining a porous ceramic material in which an organic polymeric net
surrounds inorganic ceramic parts.
Conveniently, the first composition can also comprise ceramic
materials, for example ceramic materials selected from the group consisting
of aluminum oxide, silicon oxide, titanium oxide, zirconium oxide, silicon
carbide, titanium carbide, silicon nitride, ferric oxide, magnesium
hydroxide, oxides and carbonates of alkaline and alkaline-earth metals. The
oxides of alkaline metals can be selected from the group consisting of
sodium oxide, potassium oxide, lithium oxide, and are preferably sodium
oxide.
Moreover, the first aqueous composition can comprise a
polymerization catalyst.

Examples of compounds capable of destabilizing said first colloidal
composition with gel formation are organic and inorganic acids, silica,
esters, ethers, anhydrides and salts of organic and inorganic acids, organic
electrolytes, borates, carbonates, carbides, nitrites, nitrides, ammonium
salts, oxides, peroxides, silicates, phosphates, phosphites, sulfates,
chlorides, selenides, titanates.
Examples of compounds capable of forming, when said second
composition is mixed with said first composition, an organic polymeric
mesh and compounds adapted of forming a blowing agent are one or more
compounds of the group constituted by organic polymerizable monomers
and/or organic compounds adapted to provide, by reaction with water,
organic polymerizable monomers, organic acid anhydrides, organic acid
esters, organic acid alkoxy esters, salts of organic acids, ethers and organic
acids and metallic acetylides.
The second composition preferably comprises calcium carbide.
Advantageously, the second composition can comprise calcium carbide,
acetic anhydride and/or ethyl acetoacetate and/or ethyl acetate.
The first composition preferably contains sodium silicate.
Advantageously, the first composition contains sodium silicate and the
second composition contains calcium carbide and acetic anhydride.
The inorganic particles of the second composition can be selected
among one or more of the compounds selected from the group consisting of
calcium carbide, potassium tetraborate, calcium carbonate, sodium
perborate, boric acid, calcium oxide, potassium sulfate and sodium sulfate.
Moreover, the second composition can comprise an emulsifier, for
example selected among the group consisting of potassium acetate, calcium
carbonate, titanium dioxide, potassium hydroxide, potassium tetracarbonate,
sodium oxide.
The mixing step of the method according to the present invention can
be carried out for example at a temperature ranging from 10 to 120°C, at a

subatmospheric, atmospheric or superatmospheric pressure, and at a weight
ratio between said first composition and said second composition ranging
from 2 to 50.
The inorganic particles can have for example an average size of less
than 100 micrometers, particularly ranging from 5 to 25 micrometers, but
can also have a nanometer size (for example, from 5 to 3.0 run, as in the case
of nanometer dust).
Brief Description of the Drawings
The characteristics of the porous ceramic material that can be
obtained by means of the method according to the present invention are also
shown by the accompanying figures, which relate to some examples of
application of the process according to the present invention.
Figure 1 is a schematic representation of an embodiment of the
method according to the present invention.
Figure 2 is a view of a detail of the organic polymeric portion that
coats the ceramic surface.
Figure 3 is a view of the same detail as Figure 2, with a different
sensor suitable to highlight, in a sort of semitransparent image, the ceramic
portions that lie below the organic polymer, which are lighter.
Figure 4 is a view of hollow regions produced by the blowing agent
(bubbles), coated internally by an organic polymeric sheath (b) and shows in
cross-section a ceramic microporous portion (a) composed of silica and
other ceramic particles without organic polymer.
Figure 5 is a view of a detail of Figure 4, highlighting portion b.
Figure 6 is a view of a detail of Figure 4, highlighting portion a.
Figures 7 and 8 are views of details of microsilica-ceramic structures.
Figures 9 and 10 are views of details of the interactions between the
silicaceramic and organic polymer.
Ways of carrying out the Invention
The following are some parameters which can affect the morphologic

characteristics of the material:
- percentage of silica, modulus of the initial polysilicate solution SiO2/M2O
with respect not only to Na2O but also to the other alkaline metals
depending on their stability in the silanol system of the solution in H2O. For
example in industrial solutions of colloidal sodium silicate, this ratio is
expressed as a weight ratio R; this ratio is available in a range of solutions
which are more or less rich in silica, usually from Na2O 1.6SiO2 to
Na2O-3.8SiO2 and in various intermediate ratios. Another important
parameter of polysilicate sols is expressed in °Bè (degrees Baumé), a value
which is expressed to indicate the concentration of the solutions. Similar
parameters can be found in the other solutions of colloidal silica with other
alkaline metals, such as for example in potassium silicate.
- percentage and nature of the ceramic particles of mixture A which are
stable and must be selected depending on the composition of the final
ceramic product. In general, A12O3, SiO2, TiO2, ZrO2, SiC, TiC, SiN, CaCO3,
MgCO3, Mg(OH)2, Fe2O3 and other oxides and carbonates of metals, in such
percentages as to not compromise the stability of the polysilicate solution,
paying particular attention to variations in pH, which must not be lower than
pH 10.
- percentage and manner of the addition of the organic components in
mixture B and their ratio with the other inorganic components (with
particular reference to components such as calcium carbide) and of course
their interaction, if any, and degree of polymerization of the organic
components (which can be obtained by means of microscopic optical-
chemical measurements aimed at identifying their three-dimensional
structure and stability over time).
- weight ratio of the relation A/B in terms of both weight and volume, by
means of their density and partial individual percentages. This ratio was
verified with experimental tests as being variable, with B = 2% to 35% by
weight of A.

- Flocculating properties (of aggregation and clustering) linked to the
miscibility of suspensions A and B and of the method in its several steps.
-Total rate of A+B chemical reactions in relation to their dynamic mixing.
These variables are affected by the characteristics of the system used to
perform their mixing.
- Viscosity and density of the suspensions A and B.
- Time and temperatures of the process.
It is therefore evident that the variables of the materials and processes
are certainly related to the morphologic properties of the ceramic product, in
its final location after injection, the granular structure and the cells (number
and size), and any diversification thereof in their structural physical
properties.
Substantially, the method according to the present invention
comprises the mixing of two distinct stable compositions, a composition in
the form of a solution or suspension of colloidal silica based on water (A)
and a composition in the form of a suspension of inorganic particles in an
organic liquid o in a mixture of organic liquids of (B), which can be
prepared and deposited separately for a long time without undergoing
modifications.
In one embodiment, a new hybrid ceramic-organic material is
obtained by means of the method according to the present invention by
mixing:
- A stable solution A of colloidal silica comprising, in dispersion, other
ceramic particles depending on the ceramic-organicized type to be
developed.
- A stable suspension B of organic liquids comprising, in dispersion, other
organic and inorganic particles adapted to destabilize and trigger the
polymeric condensation of the suspension A in A+B.
The two reacting suspensions, "A" and "B", used in the method
according to the present invention are prepared separately by mixing

uniformly first the powders in suspension in the respective solvents. In case
A, they are for example: liquid sodium silicate in the state of colloidal
aqueous aggregation of SiO2 with the addition of powders of metals, oxides
and carbonates of metals and alkaline metals. In case B, they are for
example: acetic anhydride and ethyl acetoacetate, both liquid as
destabilizing agents of SiO2 of the electrolytic type, with the addition of
oxides, carbonates, borates of metals and alkaline metals, once mixed with
the suspension A they become responsible for the conversion from the
colloidal state of the silica to a gel state depending on the pH of the mixture
composed of A+B. In this phase transition, siloxane condensation occurs by
using as base the organic polymeric formations, which also originate from
reactions which are the result of A+B. In this hybrid organic-inorganic
polymeric condensation, a network formed by the ramified chains having a
three-dimensional structure is consolidated, said chains inserting in the
mesh of the net polymerized chemical compounds both as silica chains and
as colloidal silica particles, even and especially in the presence of alkaline
substances, which occupy the large spaces of the colloidal tetrahedral
structure of silica, forming, as in glass, alkaline-metal polysilicates,
hydroxides and carbonates.
It should be noted that the ceramic particles are not indispensable for
carrying out the reaction but affect the performance of the resulting
material.
One might therefore summarize that for example the following steps
occur during the method of the present invention:
- A dispersion 1A of the ceramic particles in a colloidal solution of silica A
- A dispersion 1B of the destabilizing particles in a mixture of organic
liquids with a polymeric matrix B
- A destabilization 2 in A+B by means of organic and inorganic compounds
present in B or generated by mixing A and B, which may or may not
polymerize but certainly contribute to the conversion from sol to gel.

- The polymerization 3 of the organic elements, simultaneous with the step
of siloxane condensation from sol to gel, thus allowing the formation of an
organic skeleton during two processes: a process for formation expanding
gases; a process of agglomeration of the polysilicate ceramic particles,
which by amalgamating with the organic skeleton by way of
organofunctional silanol bonds or simply interactions of ion affinity, form
the porous organicized ceramic structure of the present invention.
- The drying 4 allows to accelerate the process of elimination of the excess
solvent and can be carried out at temperatures ranging from 40 to 160° C
without altering the morphologic properties of the material. This operation
can be carried out in ovens or directly at the installation location, by using a
controlled and gradual temperature rise.
- The sintering 5 is optional and allows to consolidate a three-dimensional
structural construction by amalgamating the silicate alkaline metal
compounds like a true ceramic, thus improving the physical features of the
material. It should be noted that by raising the material to sintering
temperature, pyrolization of the polymeric organic structure occurs
In a particular embodiment, composition A is a stable colloidal
solution of sodium silicate and composition B is a stable suspension
containing calcium carbide, acetic anhydride and ethyl ester.
In other preferred embodiments, composition A contains also one or
more compounds selected among zirconium dioxide, calcium carbonate,
alumina, magnesium carbonate, titanium oxide and aluminum.
In one embodiment, composition A comprises the colloidal solution
of sodium silicate and composition B comprises powder of calcium carbide,
acetic anhydride and ethyl ester.
In another embodiment, composition A comprises a colloidal solution
of sodium silicate, powder of alumina and powder of ferric oxide and
composition B comprises powder of calcium oxide, powder of calcium
carbide, powder of silica, powder of potassium sulfate, acetic anhydride and

ethyl acetate.
In another embodiment, composition A comprises a colloidal solution
of sodium silicate, powder of titanium dioxide, powder of alumina, powder
of ferric oxide and powder of aluminum and composition B comprises
potassium tetraborate, potassium acetate, calcium carbide, silica, calcium
carbonate, acetic anhydride, ethyl ester and ethyl acetate.
Without intending to be bound by a specific hypothesis regarding the
mechanism, one can assume that the process according to the invention, in
particular embodiments, occurs after the mixing of the components A and B
according to the following main substeps:
SUBSTEP 1
- the calcium carbide of mixture "B" reacts with the H2O of mixture "A";
CaC2 + 2H2O → Ca(OH)2 + C2H2↑
- the acetic anhydride of mixture "B" reacts with H2O of mixture "A";
(CH3CO)2 O + H2O → 2CH3COOH
- the ethyl ester of mixture "B" reacts with the sodium hydride (a base
alcohol) of mixture "A";
CH3COCH2COOCH2CH3 + 2NaOH → 2CH3COONa + C2H5OH
The compounds that have formed in the first subphase react by
forming organic polymers which constitute the organic skeleton. These
reactions develop simultaneously, and at a higher concentration, in the
formation of the porous cells due to the dual effect of the blowing agent.
This agent behaves as a blowing agent, forming open and closed cells, and
has the fundamental role of initiator of the organic polymeric condensation
reactions.
The resulting organic polymeric structure behaves like a sheath, i.e., it
acts like a skeleton, wraps around the inorganic structures of the
polysiJicates, providing the support required for consolidation of the
siloxane chains formed by the phase transition from sol to gel.
SUBSTEP 2

- Acetic acid combines with acetylene and reacts, producing polyvinyl
acetate;
CH3COOH + C2H2 → (CH2CHOCOCH3)n
- Sodium acetate combines with acetylene and water, and reacts producing
polyvinyl acetate and sodium hydroxide;
CH3COONa + C2H2 + H2O → (CH2CHOCOCH3)n + NaOH
- Potassium acetate combines with acetylene and water, and reacts
producing polyvinyl acetate and potassium hydroxide;
CH3COOK + C2H2 + H2O → (CH2CHOCOCH3)n + KOH
-Ethyl alcohol combines with calcium carbide and water, and reacts
producing calcium hydroxide and ethylene:
2C2H5OH + 2CaC2 + H2O → 2Ca(OH)2+2C2H4↑
- Acetic acid combines with calcium carbonate and reacts, producing
calcium acetate, water and carbon dioxide;
2CH3COOH + CaCO3 → Ca(CH3COO)2 + H2O + CO2↑
SUBSTEP3
The organic polymeric chains which have formed in subphase 2
undergo further reactions in the presence of the alcohol base of sodium.

Thus, the final organic skeleton is obtained, which can be defined
chemically as a polymeric condensation of secondary valency with

intermolecular and intramolecular bonds of the ramified type of a copolymer
of polyvinyl alcohol and polyvinyl acetate having a certain molecular
weight containing impurities such as acetates of K, Ca, Na, comprising
organofunctional silanol and polysilanol bonds.
Simultaneously with the polymerization reactions, the pH values drop
and the alkaline polysilicates condense, including the ions and other
inorganic molecules that are present, which are attracted by the negative
charge of the electrolytic organic components of the organic skeleton after
the mixing of A+B, where formations occur of the organicized ceramizing
amorphous silicates and carbonates in the glassy or crystalline state with
the porosities produced by the blowing gas activities, such as predominantly
C2H2 and, occasionally, CO2 and C2H4 which are present as a consequence of
the composition of the reagents.
Examples
Merely by way of nonlimiting example for the scope of the present
invention, the following examples of compositions A and B used in in the
method according to the present invention are presented.
















Moreover, for the sake of completeness, it should be added that it is
conveniently possible to obtain different characteristics of the final material
from a same initial formulation by subjecting reagent B to a thermal
treatment and subsequent milling.
In this regard, taking for example as reference the formulation of
reagent B according to Table 5.2 of Example 5 and, more specifically, the
boric anhydride and the calcium carbide contained therein, it is possible to
vary important characteristics of the final ceramic material, such as the
morphology and size of the cells, by subjecting a mixture of these powders
to accurate mixing and melting at temperatures preferably ranging from
500°C to 1500°C. At the end of the thermal treatment, the resulting material
is subjected to milling and screening in order to obtain the intended particle
size, which can for example range from 5 to 25 um. Optionally, it is
possible to subject to the same thermal treatment also other powders
together with calcium carbide, such as for example, silicon dioxide or also
salts of organic acids or other organic or inorganic substances, adapting the
melting temperatures appropriately. In this procedure it is not necessary to
melt all the powders together, but it is sufficient to melt a single component

to achieve the agglomeration of the other components with a higher melting
point.
The method according to present invention allows to obtain a porous
ceramic material which comprises portions of silica, optionally aggregates
of silica and of ceramic portions, which constitute a separate inorganic
portion which is contained in a separate organic net which acts as a skeleton
and support for the inorganic portion, for the ceramic particles, even if they
are agglomerated, with porosity, in which the organic net is provided by
polymerization and might not only surround the inorganic portion but be
bonded to it.
Although only some embodiments of the invention have been
presented in the description, the person skilled in the art will understand
immediately that it is in any case possible to obtain other equally
advantageous and preferred embodiments.
The disclosures in Italian Patent Application No. VR2006A000035
from which this application claims priority are incorporated herein by
reference.

CLAIMS
1. A method for preparing a porous ceramic material, particularly for
thermal insulation, comprising the steps of:
-providing a first composition in the form of a stable aqueous
colloidal solution of silica and oxides of alkaline metals;
- providing a second stable composition in the form of a suspension
in an organic liquid of inorganic and/or organic particles, said second
composition containing compounds which, when said second composition is
mixed with said first composition, can destabilize said first composition,
forming gel, and can form an organic polymeric net together with a blowing
agent;
- mixing said first composition and said second composition to form a
mixture;
- forming from said mixture a porous structure in gel form, where an
organic structure supports inorganic structures being formed;
- solidifying said porous structure in gel form, obtaining a porous
ceramic material in which an organic polymeric net surrounds inorganic
portions.

2. The method according to claim 1, characterized in that said first
composition also comprises ceramic materials.
3. The method according to claim 2, characterized in that said ceramic
materials are selected from the group consisting of aluminum oxide, silicon
oxide, titanium oxide, zirconium oxide, silicon carbide, titanium carbide,
silicon nitride, ferric oxide, magnesium hydroxide, oxides and carbonates
of metals.
4. The method according to claim 1, characterized in that said oxides
of alkaline metals are selected from the group consisting of sodium oxide,
potassium oxide, lithium oxide, and are preferably sodium oxide.
5. The method according to one of claims 1 to 4, characterized in that
said first aqueous composition further comprises a polymerization catalyst.

6. The method according to one of claims 1 to 5, characterized in that
said compounds capable of destabilizing said first colloidal composition
with formation of a gel are selected from the group consisting of organic
and inorganic acids, silica, esters, ethers, anhydrides and salts of organic
and inorganic acids, organic electrolytes, borates, carbonates, carbides,
nitrites, nitrides, ammonium salts, oxides, peroxides, silicates, phosphates,
phosphites, sulfates, chlorides, selenides, titanates.
7. The method according to one of claims 1 to 6, characterized in that
said compounds capable of forming, when said second composition is
mixed with said first composition, an organic polymeric net and
simultaneously a blowing agent are selected among one or more compounds
of the group consisting of organic compounds adapted to provide by
reaction with water, organic polymerizable monomers, organic acid
anhydrides, organic acid esters, organic acid alkoxy esters, salts of organic
acids, ethers and organic acids and metallic acetylides.
8. The method according to one of claims 1 to 7, characterized in that
said second composition comprises calcium carbide.
9. The method according to claim 8, characterized in that said second
composition comprises calcium carbide, acetic anhydride and/or ethyl
acetoacetate and/or ethyl acetate.

10. The method according to any one of the preceding claims,
wherein the first composition contains sodium silicate and the second
composition contains calcium carbide and acetic anhydride.
11. The method according to any one of the preceding claims
characterized in that said inorganic particles are selected among one or more
of the compounds selected from the group consisting of calcium carbide,
potassium tetraborate, calcium carbonate, sodium perborate, boric acid,
boric anhydride, calcium oxide, magnesium oxide, magnesium peroxide,
silicon dioxide, aluminum hydroxide, potassium hydroxide.
12. The method according to any one of the preceding claims,

characterized in that said second composition comprises an emulsifier.
13. The method according to claim 12, characterized in that said
emulsifier is selected from the group consisting of potassium acetate,
calcium carbonate, titanium dioxide, potassium hydroxide, potassium
tetracarbonate, sodium oxide.
14. The method according to any one of the preceding claims,
characterized in that said mixing stage is carried out at a temperature from
10 to 120°C, at a subatmospheric, atmospheric or superatmospheric
pressure, and at a weight ratio between said first composition and said
second composition ranging from 2 to 50.
15. The method according to any one of the preceding claims,
characterized in that said inorganic particles have an average size of less
than 100 micrometers, particularly ranging from 5 to 25 micrometers.
16. The method according to any one of the preceding claims,
characterized in that said inorganic particles have nanometer-scale
dimensions, preferably ranging from 5 to 30 run.
17. The method according to any one of the preceding claims,
characterized in that at least one of the components of said second
composition is subjected to a thermal treatment and subsequent milling.
18. The method according to any one of the preceding claims,
characterized in that said thermal treatment occurs at a temperature
substantially ranging from 500°C to 1500°C.
19. The method according to any one of the preceding claims, further
comprising the steps of:
- introducing said gel, before said solidification, in a mold, an
interspace or a cavity by injection or extrusion of said gel; followed by
- solidifying the gel in situ in said mold, interspace or cavity,
obtaining a porous ceramic material in which an organic polymeric net
surrounds inorganic ceramic parts.
20. A porous ceramic material, particularly for thermal insulation,

obtainable by the method according to one or more of the preceding claims.

The present invention relates to a method for
preparing a porous ceramic material, particularly for
thermal insulation, comprising the steps of
providing a first composition in the form of a stable
aqueous colloidal solution of silica and oxides of
alkaline metals; providing a second stable
composition in the form of a suspension in an organic
liquid of inorganic and/or organic particles, the
second composition containing compounds which, when
the second composition is mixed with the first
composition, can destabilize the first composition,
forming gel, and can form an organic polymeric net
together with a blowing agent; mixing the first
composition and the second composition to form a
mixture; forming from the mixture a porous structure
in gel form, where an organic structure supports
inorganic structures being formed; solidifying the
porous structure in gel form, obtaining a porous
ceramic material in which an organic polymeric net
surrounds inorganic portions.

Documents:

03010-kolnp-2008-abstract.pdf

03010-kolnp-2008-claims.pdf

03010-kolnp-2008-correspondence others.pdf

03010-kolnp-2008-description complete.pdf

03010-kolnp-2008-drawings.pdf

03010-kolnp-2008-form 1.pdf

03010-kolnp-2008-form 2.pdf

03010-kolnp-2008-form 3.pdf

03010-kolnp-2008-form 5.pdf

03010-kolnp-2008-international publication.pdf

03010-kolnp-2008-international search report.pdf

03010-kolnp-2008-pct priority document notification.pdf

03010-kolnp-2008-pct request form.pdf

03010-kolnp-2008-translated copy of priority document.pdf

3010-KOLNP-2008-(09-04-2014)-ABSTRACT.pdf

3010-KOLNP-2008-(09-04-2014)-ANNEXURE TO FORM 3.pdf

3010-KOLNP-2008-(09-04-2014)-CLAIMS.pdf

3010-KOLNP-2008-(09-04-2014)-CORRESPONDENCE.pdf

3010-KOLNP-2008-(09-04-2014)-OTHERS.pdf

3010-KOLNP-2008-(09-04-2014)-PETITION UNDER RULE 137.pdf

3010-KOLNP-2008-(16-04-2014)-CORRESPONDENCE.pdf

3010-KOLNP-2008-(16-04-2014)-FORM-1.pdf

3010-KOLNP-2008-CORRESPONDENCE-1.1.pdf

3010-KOLNP-2008-CORRESPONDENCE-1.2.pdf

3010-KOLNP-2008-CORRESPONDENCE-1.3.pdf

3010-KOLNP-2008-FORM 18.pdf

3010-KOLNP-2008-OTHERS-1.1.pdf

3010-KOLNP-2008-OTHERS.pdf

3010-KOLNP-2008-PA.pdf

abstract-03010-kolnp-2008.jpg


Patent Number 263482
Indian Patent Application Number 3010/KOLNP/2008
PG Journal Number 44/2014
Publication Date 31-Oct-2014
Grant Date 30-Oct-2014
Date of Filing 24-Jul-2008
Name of Patentee Z. G. CAMINI INOX S.R.L.
Applicant Address VIA DEI PESCHI, 12 37141 VERONA
Inventors:
# Inventor's Name Inventor's Address
1 GERMANO ZAMBALDO C/O. Z. G. CAMINI INOX S.R.L. VIA DEI PESCHI, 12 37141 VERONA
PCT International Classification Number C04B 14/04
PCT International Application Number PCT/EP2007/001379
PCT International Filing date 2007-02-16
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 VR2006A000035 2006-02-20 Italy