DE1167232B - Coats and moldings of pearlescent appearance - Google Patents

Description

Coatings and moldings of pearlescent appearance. The invention relates to coatings and moldings of pearlescent appearance and is characterized by the Use of a specific mother-of-pearl pigment marked that. When mixed in a suitable carrier in this gives the desired mother-of-pearl effect.

Mother-of-pearl compositions are in various. Forms and known for a wide variety of purposes; they serve to get different To give objects a pearly or mother-of-pearl appearance. Be like that for example in the production of fake. Glass or plastic beads with beads a suspension of mother-of-pearl pigment in a suitable carrier such as Cellulose nitrate varnish, coated. In the manufacture of knife handles and fountain pens With mother-of-pearl imitation, mother-of-pearl pigment is mixed into a plastic such as, for example Cellulose acetate, which is then given the desired shape. Pearl plates are made by casting polymerizable resins such as acrylic or polyester resins in which mother-of-pearl pigments are suspended. The plates can be sliced to make imitation mother-of-pearl buttons will.

To achieve the mother-of-pearl effect, such compositions are various mother-of-pearl pigments known. A widely used mother-of-pearl pigment is Pearl-Essence, which is a suspension of the platelet-shaped guanine crystals that is obtained from certain fish scales. Other pearlescent pigments consist of suspensions of crystals of lead hydrophosphate or basic lead carbonate or also mica flakes in suitable carriers.

By incorporating such pigment crystals into a translucent one organic carrier material, especially in plastic or synthetic resin media the characteristic pearlescent luster achieved; for this it is necessary that the pigment crystals are oriented in parallel layers in the carrier medium; the orientation becomes made possible by the platelet shape of the crystals. The characteristic mother-of-pearl shine comes about because the light goes in a given direction at the same time reflects off a variety of surfaces; because the intensity of the reflection at the interface of two transparent media from the difference in the refractive indices depends, the refractive index of the pigment crystals must differ from that of the carrier medium. Furthermore, the mother-of-pearl pigment used must be in water and in the plastics processing in each case used organic liquid compounds relatively insoluble be; the melting or decomposition point of the pigment substance used in each case should be high compared to the temperatures occurring during plastics processing lie.

In practice, the commonly used resins and plastics have refractive indices roughly in the range from 1.5 to 1.6 and the mother-of-pearl crystals have refractive indices greater than .1.7. The refractive indices for lead hydrophosphate crystals are, for example, 1.86, 1.83 and 1.81, those for crystals made of basic lead carbonate are 2.09 and 1.94.

From the above considerations it follows that the requirements mentioned (with regard to the refractive index, the solubility, the melting or decomposition point etc.) with the known use of guanine or other inorganic crystals as a mother-of-pearl pigment for the possible combinations of pigment and carrier medium as well as with regard to the manufacturing and processing methods to be observed Set conditions that are relatively narrow. Also with regard to the achievable There is a play of colors in view of the inherent color of the inorganic crystals mentioned only limited variation possibilities. And finally, those mentioned are inorganic Some crystal pigments are relatively expensive. The present The invention thus proceeds from the known use of inorganic crystal flakes as a mother-of-pearl pigment in translucent carrier media; through the invention are intended to address the disadvantages and limitations mentioned, which arise when using the known Mother-of-pearl pigments should be avoided if possible.

For this purpose, according to the invention, is the use of glass flakes with a thickness up to 2 microns and an average ratio of length to thickness of at least four as a mother-of-pearl pigment in a translucent organic Support material provided, the refractive index of the glass flakes by at least 0.2 greater than that of the substrate. Glass plates are preferably used, whose length is in the range of 2 to 100 microns and whose refractive index is at least Is 1.7.

The invention is based on the knowledge that even with glass, d. H. a non-crystalline material, a surprisingly good mother-of-pearl pigment Mother-of-pearl effect can be achieved, provided that the above conditions (with regard to Plate shape, plate thickness and refractive index of the glass used) are. Compared to the known use of crystalline substances as mother-of-pearl pigment offers the use of glass flakes according to the invention as mother-of-pearl pigment a number of advantages; the glass pigment is in most solvents and Chemicals less soluble, more resistant at higher temperatures and during processing less sensitive than the mentioned crystalline pigments. Then there is the cheapness of the starting material for the mother-of-pearl pigment, the many possible variations in terms of coloring and the simplicity of the manufacturing process for the pigment and the pearlescent composition.

It is already known to use solid particles in molded and molded parts made of synthetic resin, including, among other things, small splinters of glass to be stored; embedding the However, glass splinters are not used to achieve a mother-of-pearl effect, but to make the synthetic resin body, which is inherently clear, opaque do. Furthermore, it is already known per se to paint flakes of glass to constrict; Here too, however, the glass flakes should again be mixed in not any visual effects are achieved, but rather only certain physical properties of the coating, such as lower thermal conductivity, improved electrical insulation properties, increased spreadability of the paint and a lower tendency of the paint to crack or peel off will. After all, one has already suggested using a synthetic resin or other Plastic mass in the semi-liquid or pasty state to achieve certain Iridescent, mother-of-pearl or enamel effects, pigments such as dyes, metal powder or -crystals as well as glass, among other things. So far as glass in question there is no further information regarding the use (regarding form, Dimensions and optical properties of the glass particles).

The glass flakes are preferably used according to the invention in the form of a paste-like suspension in an aqueous or organic liquid for incorporation into the carrier material. In particular, the glass platelets can according to of the invention as a mother-of-pearl pigment in a resinous carrier material with a Refractive index from about 1.5 to 1.6, preferably a synthetic resin from the group of acrylic resins, polyester resins and casein resins can be used.

According to the invention, the glass flakes can be used as mother-of-pearl pigment in a molded body made of the carrier material mentioned can be used or alternatively also as a mother-of-pearl pigment in a lacquer, preferably a nitrocellulose-butyl acetate lacquer.

Further advantages and details of the invention emerge from the following description.

Lamellae are produced from different glass compositions, their Dimensions are comparable with those of the aforementioned mother-of-pearl-like crystals. If you mix these glass plates with a carrier substance, they give a pearlescent luster, which is similar to that of the well-known mother-of-pearl pigments. The well-known pearl effects are either achieved by covering surfaces with these platelets or that one blends the platelets in clear plastic compositions.

According to a suitable method for producing the flakes, extremely thin films are first blown from the suitable glass. The film thickness should be 2 microns or less and is of the correct order of magnitude if the films exhibit interference colors, although film thicknesses just below and above this value are still in the desired range. To produce platelets from the film, the latter is suspended in water or another liquid and vigorously moved back and forth or ground in a suitable device, for example a ball mill. Samples are taken from the suspension at short intervals (for example only 30 seconds) and examined microscopically to determine the size of the broken particles. The process is terminated as soon as the glass film has been crushed into flakes, the length of which is preferably between 2 and 100 microns. It is further desirable that the length to strength ratio be at least four, ie. Particles 2 microns long are suitable if their thickness is 0.5 microns or less, whereas platelets 2 microns thick should be at least 8 microns long. Although lengths of 2 to 100 microns give optimal gloss, lamellas less than 2 microns in length are also suitable if they are thin enough, the main condition being that the particles retain platelet shape, which, as indicated above, is then taken for granted may if the length / thickness ratio is four or more. If a few small particles with a lower ratio of length to thickness are produced during the breaking process, the mother-of-pearl effect of the appropriately shaped platelets is weakened, but of course not completely eliminated.

Platelets more than 100 microns in length also give a pearl-like appearance Gloss, however, is less desirable for a variety of reasons because of individual particles can be perceived by the eye and thus a discontinuous optical effect cause. The resulting suspension of glass flakes has the typical silky appearance of mother-of-pearl suspensions. She is both in terms of the platelet size and the platelet thickness are inconsistent. If desired, the lamellae can be settled and decanted or centrifuged fractionate into groups of more uniform size. The thinner particles, which in relation to the weight of the glass give the strongest gloss, since they have the largest number reflective surfaces are particularly suitable for use, for example, for surface coating suitable for fake pearls, while the somewhat thicker platelets are suitable for shaping Of plastics are preferable, the greater strength of these particles prevents them from moving in the viscous, molten plastic continue to be broken.

Another method of manufacturing the platelets is from With the help of internal blowing agents, the glass is formed into a foam with extremely thin walls generated.

The foam glass produced in this way is broken as described above and fractionated to obtain particles of the desired dimensions. With others Methods for producing the thin film are the known extrusion and calendering processes applied.

Further advantageous properties of the glass lamellae emerge in detail from the following description of exemplary embodiments. Example 1 A flint glass with the composition 35.4011 / o SiO. "5.16% K., 0.59.10% Pb0, 0.34% ASZ03 and the refractive index nD = 1.70 turns into a thin film of less The film is dispersed in butyl acetate and then broken by agitation to form particles an average of 35 microns in length A paste consisting of 25% glass in butyl acetate remains. 96.0 parts of a lacquer consisting of 8.0% cellulose nitrate (15 to 20 seconds) in butyl acetate are added to 4.0 parts of this paste of alabaster glass beads in the dipping process.

In this example it should be noted that the mother-of-pearl pigment is 25 percent by weight the paste composition. In reality, this composition can after The particular needs vary, so that the desired final pigment concentration in the actual solution used to produce the coating in the range of is about 0.25 to 5.0%. Example 2 A glass film 2 microns or thick less is produced as in example 1. The film is taken up in water and ground into particles an average of 15 microns in length. Man lets the lamellae settle out of the water that is poured off and dry the resulting paste. 2 parts of the dry pearl flakes are mixed with 198 parts Polymethyl methacrylate powder mixed. The mixture is then extruded a rod made with imitation mother-of-pearl.

Example 3 A glass made of 90.8% Sb203 and 9.2% B203, nD = 1.95, is blown and broken as described in the previous example, with styrene serving as the grinding liquid. The resulting suspension has particles an average length of 25 microns. The lamellae are fractionated into two parts by settling, one containing mainly the thicker platelets and the other containing mainly the thinner particles. A quantity of the glass styrene paste containing 1.0 part of glass from the thin fraction is diluted with polyester casting resin to a total of 100 parts and the mixture is poured into the form of a pearl plate from which polyester pearl buttons can be cut. The same amount of the thicker flakes is dried and the glass is then added to 99 parts of polystyrene powder, from which polystyrene bead articles are produced by injection molding. EXAMPLE 4 Glass lamellae are produced by foam formation from a glass with the composition 11.71 / o SiO 2, 1.7% Na 20, 86.6% PbO with nD = 2.08. The foam is broken up and ground to produce flakes of the dimensions given above. Example 5 Glass lamellae are produced according to Example 1 from a glass with the composition 20.1% SiO2, 29.50 / 0 Na20, 50.4% Ti02 with nD = 1.80.

The glass lamellas described have before the crystals which ones so far used to create pearlescent effects have many advantages. they are Resistant to acidic solutions and are therefore free of acid in the polyester casting resin not attacked, as is the case, for example, with basic lead carbonate Case may be. Although glasses are attacked in some ways by alkaline solutions they are nonetheless more resistant to alkali than those previously used crystalline substances and can therefore be poured into alkaline melamine resin solutions will. The use of conventional pearlescent crystals when blending in plastic molding powder requires great care to avoid overheating of the material with subsequent decomposition or discoloration of the crystals to avoid. The softening temperatures the glasses are so high that they can be processed without difficulty in this type of processing can be used.

In addition, it is not yet possible to use the conventional pearlescent To produce pigments in the form of dry powders without any loss of quality, which is usually the case caused by the agglomeration of many platelets to form undefined lumps will. The glass flakes described do not show this tendency and can therefore easily manufactured as dry raw materials for such applications in who prefer dry materials. This is generally the case with such Applications the case with which the mother-of-pearl-like material with Plastic molding powder is mixed.

The glass flakes can also be used in casein plastics. In this case, the presence of organic solvents is not required, and it is convenient to use the pearlescent pigment in the form of an aqueous paste to manufacture. In general, the desired effects can be achieved if the concentration of the glass crystals is 2 to 5 percent by weight of the casein.

Claims (7)

Claims: 1. Use of glass plates with a thickness of up to to 2 microns and an average length to thickness ratio of at least four as mother-of-pearl pigment in a translucent organic carrier material, wherein the refractive index of the glass flakes is at least 0.2 greater than that of the Carrier material is. 2. Use of glass flakes according to claim 1, the length of which ranges from 2 to 100 microns. 3. Use of glass plates according to the preceding claims with a refractive index of at least 1.7. 4. Use of glass flakes according to the preceding claims in the form of a pasty Suspension in an aqueous or organic liquid for incorporation into the carrier material. 5. Use of glass flakes according to the preceding claims as a mother-of-pearl pigment in a resin-like carrier material with a refractive index from about 1.5 to 1.6, preferably a synthetic resin from the group of acrylic resins, Polyester resins and casein resins. 6. Use of glass plates according to the previous one Claims as a mother-of-pearl pigment in a shaped body made from the carrier material. 7. Use of glass flakes according to Claims 1 to 5 as a mother-of-pearl pigment in a lacquer, preferably a nitrocellulose-butyl acetate lacquer. Documents considered: German Patent No. 693 297; French Patent Nos. 670044, 684957, 1096 488; U.S. Patent No. 2,353,995.