FR3105216A1 - CERAMICS AND MANUFACTURING PROCESS - Google Patents

Abstract

The invention relates to a ceramic and its manufacturing process, the ceramic comprising clay is mixed with mica particles of a size less than or equal to 100 µm, said mica having an iron content of at least 80% by weight based on the weight of the mica. Said ceramic can also consist at least partially of sludge from effluents from the manufacture of ceramics.

Description

CERAMICS AND MANUFACTURING PROCESS

The present invention relates to the field of ceramics and more particularly ceramics for tableware, kitchenware and ornaments, known as domestic ceramics.

If the invention can extend to all sectors of activity of ceramics, by ceramic is preferably meant, in the present text, an inorganic material, generally clay-based, which has been permanently transformed by firing. , in a material covering at least terracotta, porcelain, earthenware and stoneware.

Whatever the ceramic, the industrial manufacturing process always includes the preparation of a ceramic paste by mixing raw materials in particulate form, traditionally in water, shaping the piece, drying to obtain a shard. The latter is then subjected to high temperature firing (between approximately 1200 and 1400°C), during which the decomposition of the sheet structure of the starting clays, the formation of new crystalline structures and the formation of the phases occur. vitreous, and which leads to ceramics. For the manufacture of domestic ceramic pieces in particular, this process may also comprise a step of finishing the ceramic piece by enamelling or engobing or any other suitable decoration technique, this step possibly including an additional firing step if it is carried out after the baking above. Enameling consists of applying the mineral components of the enamel to the ceramic, either dry or in the form of an aqueous suspension, on a raw piece, after it has been sharpened or after biscuiting, then in subjecting the ceramic thus treated to a new firing leading to enamel vitrification. The engobe is made by applying an aqueous suspension of engobe components whose composition is much richer in clay than that of enamel, generally before firing the ceramic. The finish obtained depends on the nature of the components of the decoration, their proportions and the heat treatment. Other decorating techniques include hand painting, transfer decorating, laser sintering or spraying.

In the present text, the expression "raw materials" defines all the ingredients entering into the composition of the ceramic paste, i.e. the mineral(s) such as clay, feldspar, limestone, quartz , but also all additives such as fluxes, deflocculating agents, expansion agents and other agents well known to those skilled in the art.

The term “clay” designates any clay or any mixture of clays that can be consumed to prepare a ceramic paste or engobe. Examples include kaolins (white sedimentary clays), halloysites, “ball clays” (also called plastic clays), montmorillonites, bentonites.

We will retain the term "ceramic" to designate the ceramic material in general, and we will reserve the expression "ceramic part" for the finished article resulting from the firing process.

The different classes of ceramics above, terracotta, porcelain, earthenware and stoneware, have their own characteristics which essentially result from the nature and proportion of the raw materials used, the shaping processes, as well as the firing temperatures and in particular temperature gradients applied during cooking.

Thus, a porcelain presents a white, non-porous and translucent shard at low thickness. It contains mullite crystals and a vitreous phase in high proportion and is obtained by firing at a temperature of approximately 1200 to 1400°C, a mixture of around 20 to 55% kaolin, from 0 to 20 % clay other than kaolin, 15 to 30% feldspar and 0 to 30% quartz (expressed by weight relative to the weight of the mixture). Inorganic dyes can be added to this mixture in order to obtain a colored paste.

A sandstone is characterized by a vitrified structure, not very porous and opaque. It is often colored. It is obtained by firing at a temperature of around 1100 to 1300°C, a mixture of around 25 to 50% clay other than kaolin, 0 to 25% kaolin, 25 to 35 % filler (such as quartz, chamotte, etc.) and 15 to 20% fluxes, such as feldspar, alkaline-earth compounds (expressed by weight relative to the weight of the mixture).

Earthenware is characterized by a very porous structure (around 5 to 25%) and opaque. It can be white or colored and is obtained by cooking at a temperature between 900 and 1200°C approximately. It is composed of a mixture of around 40 to 70% kaolin, 30 to 60% quartz and 10 to 20% chalk or 5 to 15% feldspar.

The decoration techniques make it possible to obtain a very wide variety of patterns. Ceramic pieces are thus known to have, on at least part of their surface, a spangled appearance resulting from a multitude of dots of variable sizes brought by the spitting of metallic enamels or by the deposition of effect enamels.

We also know that the color of the ceramic paste can on its own give a decoration to the ceramic piece. We note, however, that the decoration thus naturally obtained is not very marked or that it is not regular, with the presence of shards of variable sizes, not producing the expected spangled effect.

According to the invention, a ceramic piece is provided which has a spangled effect not having recourse to any other decoration technique than those mentioned above relating to the treatment of the shard, and which can be obtained by a conventional manufacturing process such as than stated above. According to a very advantageous aspect of the invention, the ceramic, and in particular the ceramic part, can also be manufactured by a process using at least partially recycling sludge from effluents from the manufacture of ceramics.

The glitter effect is provided by the addition of particles to the ceramic paste and the quality of the glitter effect observed results from the homogeneous distribution of particles of determined dimensions, in the paste and therefore in the resulting piece.

Thus according to the invention, a clay-based ceramic is provided, the clay being mixed with mica particles of a size less than or equal to 100 μm, said mica having an iron content of at least 80 % by weight relative to the weight of the mica, preferably at least 85%.

It is observed that the combination of these characteristics leads to a ceramic which, whatever the initial composition of the paste and in particular the color of its constituents and/or that which they take after firing, has a metallic appearance.

It has been discovered that, even if the preparation of the ceramic paste makes use, in whole or in part, of recycling sludges originating from effluents from the manufacture of ceramics, the ceramic produced has the same appearance as that of a ceramic made from pure pulp.

Effluents from the ceramic industry are treated in a treatment plant to separate the water from the residues, the latter essentially comprising the mineral constituents of the ceramic paste, those of the enamel and all the additives. These residues come in the form of more or less dense sludge, which can be recycled in the manufacture of ceramics. It nevertheless appeared that when the effluents derive from the manufacture of ceramics with enamelling, it could be envisaged to separate the effluents coming from the enameling and the effluents coming from the pastes in order to envisage the recycling of the latter. Depending on their origin, these sludges can have very varied compositions and colors, sometimes dull, and it has been found that the addition of mica particles according to the invention, in a ceramic paste resulting from recycling, facilitates the homogenization colors and leads to attractive glitter ceramics. Advantageously, the recycling sludge is sorted and selected before being reused, but even after only coarse sorting, the ceramic obtained is, in terms of quality and appearance, very close to that obtained from a pure paste. .

The invention is described below in more detail and it should be understood that the optional characteristics, in particular preferential, indicated can be considered alone or in any combination.

According to a preferred variant, the mica content in the ceramic paste ranges from 1.5 to 25% by weight relative to the total weight of the ceramic ingredients. In fact, we observe that below 1.5%, the glitter effect is not sufficiently visible and the color of the ceramic, which can be bland, especially if the paste comes from recycling sludge, is not not sufficiently enhanced by glitter. Beyond 25%, the qualities of the ceramic can be modified and no longer be suitable for the field targeted by the invention, namely, terracotta, porcelain, earthenware and stoneware, particularly terracotta, porcelain, earthenware and stoneware for tableware, kitchenware and ornaments.

For the purposes of manufacturing a preferred ceramic according to the invention, the ceramic paste comprises, in addition to clay and mica, feldspar, quartz and chalk. As will be described later, the sludge recycling treatment can be optimized to produce ceramic bodies with a composition close to that of a pure ceramic body.

The preferred field of the invention being that of domestic ceramics, a ceramic as described above is preferably a ceramic piece chosen from among a goblet, a bowl, a cup, a plate, a dish, a carafe, a vase. These are of course the most common pieces, and the invention is not restricted to this list, it can indeed be chosen from any other table, kitchen and ornamental item.

According to a variant of the invention, the ceramic can be engobed and then the clay-based engobe can also comprise particles of mica meeting the aforementioned characteristics and also come from recycling sludge, possibly treated.

Another object of the invention lies in a process for manufacturing a ceramic, and in particular a ceramic as set out above. It includes the classic manufacturing steps, namely preparing a clay-based ceramic paste, shaping the paste, drying it, firing it to obtain the ceramic. An additional finishing step, and in particular enamelling, engobing or decoration, can be provided before or after firing, in which process the clay is mixed with mica particles of a size less than or equal to 100 μm , said mica having an iron content of at least 80% by weight relative to the weight of the mica, or even at least 85%.

According to an advantageous implementation of the process, the ceramic paste is prepared from sludge resulting from effluents from the manufacture of ceramics. The ceramic paste may consist only of said sludge; it can also consist of any mixture of said sludge with pure clays and/or any other pure constituent of a ceramic paste. In the latter case, the sludge content is adapted to the desired ceramic.

As indicated above, the raw materials of the ceramic paste are chosen according to the desired ceramic. Generally speaking, a ceramic paste includes:

clays such as kaolins, ball clays, halloysites, montmorillonites, bentonites,

the following other mineral constituents feldspar, quartz, chalk, and

additives such as deflocculating agents, mineral colorants.

According to a variant of the process, the effluents from the manufacture of ceramics may or may not have undergone a stage of separation of the enameling effluents and the ceramic paste effluents.

The characteristics and advantages of certain aspects of the invention will emerge from the examples below illustrating the manufacture of a ceramic from recycling sludge.

Example 1: Preparation of a ceramic paste from ceramic manufacturing effluents

The following operations are performed:

The effluents are collected in the form of filter-pressed cakes; this facilitates the implementation during the preparation of pastes or engobes but also to evacuate the residual water.

The sludge is analyzed in order to select the most suitable application according to its properties; the characteristics analyzed are the general appearance of the sludge after curing, meltability, and creep.

A formulation from recycled sludge only is prepared, presenting final characteristics comparable to "virgin" pasta, in particular to meet the requirements for food contact, resistance to thermal shocks and mechanical shocks, as well as in terms of porosity; a formulation can be made from different batches of effluents of various origins, to obtain the desired properties.

In the same way, an engobe formulation is prepared from recycled sludge only containing high levels of enamels and therefore having a high fusibility.

Mica particles of a size less than or equal to 100 µm are mixed with the ceramic paste or engobe formulation, in a proportion of 5% by weight relative to the dry weight of the formulation. The addition of mica in small quantities to the formulation makes it possible to obtain a homogenization of the different batches of paste but also to bring an aesthetic side by adding a glittery aspect.

Example 2: Production of a ceramic paste from effluents

Selection of sludge batches

For this production, different batches of effluent sludge were analyzed. The sludge was therefore diluted in water with deflocculant in order to be able to cast deformation bars which are then dried and baked.

The strips are then studied by measuring the height of deformation and observing the general appearance and fusibility.

For the ^1st batch, the pieces have a brown color, a sandstone appearance and the pieces are very deformed (height = 0 mm – completely collapsed).

For the ^2nd batch, the parts have a greenish color, a sandstone appearance and the parts are deformed (height = 15 mm).

For the 3 ^rd and 4 ^th batches, the pieces have a light brown color, a sandstone appearance and the pieces are also deformed (height = 29 and 33 mm respectively).

The sludges retained are therefore those of batches 2, 3 and 4. For batch 1, other sludges must be tested in order to find materials which deform little and which could counterbalance the creep of this batch.

Making the ceramic paste

For the production of the dough, the following implementation protocol has been implemented.

Water is added in a mixer then the sludge is added gradually. Deflocculant has also been added to facilitate the thinning of the sludge. Pasta scraps (dry casting waste) were also added in order to obtain the optimal rheological parameters. When the paste has reached the expected rheological values, the mica is added to the paste in a proportion of 5% by mass relative to the dry weight of the formulation. Rheological and deformation controls are then carried out on the paste thus obtained (height = 27 mm).

The paste is then shaped by traditional casting in plaster molds or by pressure casting depending on the parts requested. The pieces are then dried and then an enameling step can be carried out. The raw paste or enamelled pieces are finally fired at high temperature.

Claims (8)

Clay-based ceramic, characterized in that the clay is mixed with mica particles of a size less than or equal to 100 µm, said mica having an iron content of at least 80% by weight relative to the weight of mica. Ceramic according to Claim 1, characterized in that the mica content ranges from 1.5 to 25% by weight relative to the total weight of the ingredients of the ceramic. Ceramic according to Claim 1 or 2, characterized in that it is chosen from terracotta, porcelain, earthenware and stoneware. Ceramic according to any one of Claims 1 to 3, characterized in that it also comprises at least one of the ingredients chosen from feldspar, quartz and chalk. Ceramic according to any one of Claims 1 to 4, characterized in that it is a ceramic piece chosen from among a goblet, a bowl, a cup, a plate, a dish, a carafe, a vase or any other tableware , kitchen and ornament. Process for manufacturing a ceramic according to any one of Claims 1 to 5, comprising the following steps:
a clay-based ceramic paste is prepared,
the paste is shaped, dried and fired to obtain the ceramic, said process possibly also comprising an enamelling, engobing or other decoration step,
said method being characterized in that the ceramic paste comprises mica particles of a size less than or equal to 100 µm, said mica having an iron content of at least 80% by weight relative to the weight of the mica. Process according to Claim 6, characterized in that the ceramic paste consists at least partially of sludge resulting from effluents from the manufacture of ceramics. Manufacturing process according to Claim 7, characterized in that the effluents from the manufacture of ceramics have or have not undergone a stage of separation of the enamelling effluents and the ceramic paste effluents.