Colored Composite Material
20250109070 · 2025-04-03
Assignee
Inventors
Cpc classification
C04B2235/5418
CHEMISTRY; METALLURGY
C09C1/625
CHEMISTRY; METALLURGY
C09C1/0015
CHEMISTRY; METALLURGY
International classification
C09C1/00
CHEMISTRY; METALLURGY
Abstract
A solid composite material (16) combining: an inorganic pigment (10) in the form of discrete particles each comprising a colored core and a coating adapted to allow light to pass through; and a matrix (12) based on metalloid or metal oxide, said matrix being adapted to allow light to pass through.
Claims
1. A solid composite material combining: an inorganic pigment in the form of discrete particles each comprising a colored core and a coating surrounding the core, said coating being adapted to allow light to pass through; and a matrix based on metalloid or metal oxide, said matrix being adapted to allow light to pass through, said matrix containing said discrete particles, said matrix being a sintered material, wherein the coating of the discrete particles is adapted to prevent interactions between the colored cores during sintering.
2. The solid composite material according to claim 7, wherein all the inorganic pigment particles have an identical coating.
3. A solid composite material comprising: an inorganic pigment in the form of discrete particles each comprising a colored core and a coating surrounding the core, said coating being adapted to allow light to pass through, said coating not including silica; and a matrix based on metalloid or metal oxide, said matrix being adapted to allow light to pass through, said matrix containing said discrete particles, said matrix being a sintered material selected from the group consisting of ceramic and glass, wherein the coating of the discrete particles is adapted to prevent interactions between the colored cores during sintering, wherein the inorganic pigment comprises a mixture of particles including a first type of particles each having a core of a first color and a second type of particles each having a core of a second color.
4. The solid composite material according to claim 7, wherein the inorganic pigment represents a volume fraction comprised between 2% and 50% of said composite material.
5-6. (canceled)
7. Solid A solid composite material comprising: an inorganic pigment in the form of discrete particles each comprising a colored core and a coating surrounding the core, said coating being adapted to allow light to pass through; and a matrix based on metalloid or metal oxide, said matrix being adapted to allow light to pass through, said matrix containing said discrete particles, said matrix being a sintered material selected from the group consisting of ceramic and glass, wherein the coating of the discrete particles is adapted to prevent interactions between the colored cores during sintering, wherein the inorganic pigment comprises a mixture of particles including a first type of particles each having a core of a first color and a second type of particles each having a core of a second color, and wherein said coating is one of: mica, alumina, zirconia, and titanium dioxide.
8. The solid composite material according to claim 7, wherein the particles of inorganic pigment have an average diameter comprised between 0.2 m and 10 m.
9. The solid composite material according to claim 7, wherein the particles of inorganic pigment have an average diameter comprised between 0.2 m and 15 m.
10. The solid composite material according to claim 1, wherein the matrix is a ceramic.
11. The solid composite material according to claim 1, wherein the matrix comprises a glass.
12. A method for producing a solid composite material according to claim 1, said method comprising the following steps: a) selecting an inorganic pigment in the form of discrete particles each comprising a colored core and a coating surrounding the core, said coating being adapted to allow light to pass through; b) mixing the inorganic pigment in powder form with the matrix in powder form; and c) sintering said powder mixture.
13. The method of claim 12, wherein all the particles of the inorganic pigment have an identical coating.
14. The method of claim 12, for creating a composite material of a given color, wherein during step a) the proportions of inorganic pigment particles selected from several predetermined types respectively having a plurality of basic colors are determined based on the given color, and the inorganic pigment particles are mixed in the defined proportions.
15. The method of claim 14, wherein said basic colors include red, green, and blue.
16. The method of claim 14, wherein said basic colors include red, yellow, and blue.
17. The method of claim 15, wherein said basic colors further include black and white.
18. A use of a composite material according to claim 1, in watchmaking or jewelry.
19. An article of watchmaking including a solid composite material according to claim 1.
20. An article of jewelry including a solid composite material according to claim 7.
21. The solid composite material according to claim 7, wherein the matrix is a ceramic selected from the group consisting of: magnesium aluminate spinel, alumina, zirconia, mica, yttria-stabilized zirconia, and titanium dioxide.
22. The solid composite material according to claim 7, wherein the matrix is a glass selected from the group consisting of: silicates, borosilicates and glasses used in the production of enamels.
23. The solid composite material according to claim 7, wherein the coating is made of a material different from the matrix.
Description
BRIEF DESCRIPTION OF DRAWINGS
[0038] The invention will be better understood by reading the following description of several of its embodiments, given as non-limiting examples with reference to the attached drawings, in which:
[0039]
[0040] and
MORE DETAILED DESCRIPTION
[0041] As explained above, the invention relates to a solid, sintered composite material for use particularly in watchmaking or jewelry, said material combining: [0042] an inorganic pigment; and [0043] a metalloid or metal oxide-based material, the matrix being adapted to allow light to pass through (in other words it is transparent or translucent).
[0044] The inorganic pigment may represent a volume fraction comprised between 2% and 50% of the composite material.
[0045] The inorganic pigment is in the form of discrete particles each comprising a colored core and a coating surrounding the core, said coating being adapted to allow light to pass through (in other words it is transparent or translucent).
[0046] The core of the inorganic pigment is selected according to the desired color to the composite material.
[0047] For blue and green, a core of an inorganic pigment based on aluminum and cobalt is selected, in particular cobalt aluminate CoAl.sub.2O.sub.4 having a spinel crystal structure. The blue or green color of the pigment and the color intensity of the pigment depend on its oxidation rate.
[0048] Apart from cobalt aluminate, it is also possible to use compounds having the following chemical formulas, the blue or green color and the color intensity also being dependent on the oxidation rate: [0049] (Co,Zn)Al.sub.2O.sub.4; [0050] (Zn, Co) (Cr,Al).sub.2O.sub.4; [0051] Co (Al, Cr).sub.2O.sub.4; [0052] CoAl.sub.2O.sub.4/Co.sub.2SnO.sub.4.
[0053] Depending on the color desired for the composite material, an element or combination of elements may be added in order to change the color of the compound. Among these elements are the following in particular: chromium, lithium, magnesium, silicon, strontium, tin, titanium, and zinc. Again, the blue or green color and the color intensity of the pigment depend on its oxidation rate.
[0054] For red and yellow, the colored core may be an oxide containing iron, chromium, aluminum, titanium, silicon, zinc, nickel, cobalt, cadmium, copper, vanadium, bismuth, and/or manganese. For example, these may be: [0055] KAl.sub.2 (AlSi.sub.3O.sub.10) (OH).sub.2; [0056] TiO.sub.2; [0057] SiO.sub.2; [0058] ZnO.
[0059] Examples of red pigments with a titanium oxide and mica base are given in the following documents: U.S. Pat. Nos. 4,344,987 A, 5,522,923 A, and 4,086,100 A.
[0060] The coating of the inorganic pigment may be produced from a material selected from: [0061] mica, for example muscovite or biotite; [0062] alumina Al.sub.2O.sub.3; [0063] zirconia ZrO.sub.2; [0064] titanium dioxide TiO.sub.2.
[0065] The inorganic pigment particles may have an average diameter comprised between 0.2 m and 10 m.
[0066] Advantageously, the inorganic pigment degradation temperature is above 1300 C. This temperature corresponds to the decomposition temperature of the inorganic pigment which causes it to change color, or in other words the temperature at which the color of the inorganic pigment is altered.
[0067] The matrix is selected such that its densification temperature under pressure, at a pressure generally less than 250 MPa, is less than the degradation temperature of the inorganic pigment, thus advantageously less than 1300 C. One can thus sinter the material under pressure at a sintering temperature that is greater than or equal to the densification temperature at said pressure and less than said degradation temperature of the inorganic pigment.
[0068] The matrix is adapted to allow light to pass through, in other words it is transparent or translucent. For this purpose, the matrix is for example prepared according to known methods for transparent ceramics. The adaptation then lies in particular in the choice of oxide and in the forming conditions, in other words the densification temperature and the pressure.
[0069] As seen above, the matrix is based on metal oxide or metalloid oxide.
[0070] The concept of a metalloid refers to a chemical element that cannot be classified in the metals or in the non-metals, its physical and chemical properties being between those of a metal and a non-metal.
[0071] Metalloids are characterized by the following properties: [0072] their oxides are generally amphoteric (those of metals are more basic and those of non-metals are more acid); [0073] they behave like semiconductors (particularly boron, silicon, and germanium).
[0074] Metalloids thus form a diagonal band in the periodic table, between metals and non-metals: [0075] Boron .sub.5B [0076] Silicon .sub.14Si [0077] Germanium .sub.32Ge [0078] Arsenic .sub.33As [0079] Antimony .sub.51Sb [0080] Tellurium .sub.52Te [0081] Astatine .sub.85At
[0082] In particular, the matrix may be a ceramic or may comprise silica, in particular a glass.
[0083] Found among the ceramic matrices usable in the context of the invention are: magnesium aluminate spinel (MgAl.sub.2O.sub.4), pure alumina or zirconia, mica, yttria-stabilized zirconia, and titanium dioxide.
[0084] Found among the matrices containing glass usable in the context of the invention are: [0085] silicates whose glass transition temperature is close to 600 C.; [0086] borosilicates, such as Pyrex, whose glass transition temperature is 850 C.; [0087] glasses typically used in the production of enamels.
[0088] A composite material according to the invention may be produced in particular by the method illustrated in
[0094] Thus, under pressure and heat, the inorganic pigment is stable while the matrix encapsulates all the inorganic pigment particles.
[0095] The sintering of the powder mixture is advantageously carried out at a pressure greater than 80 MPa.
[0096] Sintering can be achieved for example under uniaxial pressure using a SPS (Spark Plasma Sintering) press where the increase in temperature can be achieved in a few minutes.
[0097] It is also possible to complete the sintering by sintering under isostatic pressure. This involves initially pressing the powder mixture to form pellets or injecting the components by a conventional ceramic injection technique, then performing a first sintering whose effect is to close the porosities without necessarily completing the process. Sintering is then completed in a furnace which can be pressurized by gas up to 200 MPa in general.
Example 1
[0098] A magnesium aluminate spinel powder (MgAl.sub.2O.sub.4) is used as a matrix, having a particle size of 0.2 m with impurities of less than 10 ppm for Fe, Ca, Na, and less than 20 ppm for Si. One example is the powder produced by the Baikowski company under reference S30 CR.
[0099] The proportion of inorganic pigment may vary from 5% to 30% by volume.
[0100] Spinel MgAl.sub.2O.sub.4 is usually sintered at a temperature above 1800 C. In the invention, in order to preserve the inorganic pigment and maintain its intensity, the sintering is performed at about 1200 C., under very high isostatic or uniaxial pressure.
[0101] Densification of the spinel MgAl.sub.2O.sub.4 is possible within this temperature range, provided that the pressure is greater than 100 MPa.
[0102] In addition, this temperature range enables the use of a wide range of pigments without damage to them.
[0103] A dense composite ceramic material is thus obtained with a transparency that allows using the coloring of the inorganic pigment to a depth of several tens of millimeters, instead of having a color effect from only the pigment particles at the surface.
[0104] In particular, 32.76 g spinel MgAl.sub.2O.sub.4(S30 CR Baikowski) is mixed with 4.6 g red pigment (TiO.sub.2 coating on a KAl.sub.2 (AlSi.sub.3O.sub.10) (OH).sub.2 core) to obtain a mixture with 10% pigment by volume. A graphite mold 30 mm in diameter is filled with 4 g of the mixture. The mixture is sintered under pressure for 5 min in an SPS press at 1200 C. with a force of 70 kN corresponding to a pressure of 100 MPa. This yields a dense ceramic disk that is bright red in color.
Example 2
[0105] Yttria-stabilized zirconia is used as a matrix. After sintering at 1200 C. at an isostatic or uniaxial pressure above 200 MPa, this can lead to obtaining a transparent or translucent zirconia.
[0106] By mixing up to 30% by volume of red pigment (for example the pigment of Example 1) with yttria-stabilized zirconia (up to 8% of added yttria), an effect similar to that obtained with glass or spinel MgAl.sub.2O.sub.4 is thus obtained, meaning a transparent matrix with red pigments trapped inside.
[0107] Due to its transparency/translucency, the matrix thus ensures a bright color of the final material and a maximum surface area of pigments reached by incoming and penetrating light.
[0108] The invention therefore provides new ceramic composite materials with a very wide range of colors.
[0109] In particular, in order to create a composite material of a given color, the selecting and mixing of step a) can be done using a limited number of predetermined types of inorganic pigment particles, the different types of particles respectively having cores of various base colors, in proportions suitable for obtaining said given color. This mixture of particles having cores of different types, without interaction between cores during sintering, is made possible by the fact that the core of each inorganic pigment particle is surrounded by a coating. It may be particularly advantageous if particles of different types have identical coatings.
[0110] With a relatively simple production facility, a very wide range of colors can thus be obtained. In particular, one can use three predetermined types of inorganic pigment particles whose cores respectively have three basic colors, red, green, and blue (or red, yellow, blue). Optionally, one can use five predetermined types of inorganic pigment particles whose cores respectively have five basic colors, red, green, blue, black, and white (or red, yellow, blue, black, and white). The latter two (black and white) make it possible to modulate the intensity, for example in order to obtain pastel colors.
[0111] The colored composite materials of the present invention have applications in the production, for example, of housing components for watchmaking, such as bezels, case middles, wristband fasteners, etc. The advantage of these materials in this application is their wear resistance and the guarantee that the color of the components cannot be damaged by stresses on the watch when worn on the wrist.