EP1077471A1 - Coloured light emitting device with a lamp coated with a pigmented layer - Google Patents

Abstract

Colored light has a lamp and a cover, in which the lamp has a bulb with a coating with a first pigmented layer containing a perylene, perinone, isoindoline or thioindigo pigment. An Independent claim is also included for lamps with a bulb with this pigmented coating.

Description

The invention relates to a colored light, in particular a colored signal light for Automobile equipped with a lamp and a lamp cover in which the lamp a piston with a coating with a layer containing an organic pigment, Has.

Colored lights are used in various places in automobiles, for example for brake lights, indicators and fog lamps. In conventional colored lights is the bulb of the lamp made of clear glass and the lamp under a colored, mostly red or yellow lamp cover arranged. A more recent development is going for colored ones Shine colored lamps under a colorless or neutral colored cover to use. This allows different colored signal lamps as a lamp ensemble a uniform fluorescent cover.

Lights with colored lamps under a colorless or neutral colored cover have the advantage that they have a flexible, visually appealing design for integrated Allow front and rear lights. They are also cheaper than lights with multi-colored ones Housing or multi-colored covers. These lights are also even safer to drive, because the difference between on and off lighting in daylight on luminaires with colored lamps and colorless or neutral colored Luminaire cover is more recognizable.

For the colored, pigmented bulb coating of colored lamps you can Always use inorganic or organic color pigments. The well-known red and yellow inorganic color pigments are long-term stable, but do not have optimal ones Color values. Piston coatings with organic color pigments, e.g. the from the JP-A-60 116958 known coatings with red pigments from the group of Anthraquinone pigments can be optimized in terms of color coordinates, yellow with time, however.

As in many other branches of industry, the trend is also in automotive lamps Towards an ever more miniaturization. One tries the size of the lighting fixtures on the automobile as a whole and, for example, the signal lights to integrate into the headlights. In such lighting fixtures However, lamps are exposed to increased thermal loads.

It is the object of the present invention to provide a colored light fitting Lamp and a lamp cover in which the lamp has a bulb with a coating with a layer that has an organic color pigment to create the one long service life even at high ambient temperatures as well as optimal color coordinates and which is suitable for automotive lighting.

According to the invention the object is achieved by a colored lamp equipped with a lamp and a lamp cover in which the lamp has a bulb coating with a first pigment-containing layer, which is a pigment selected from the group of Perylene pigments, perinone pigments, isoindoline pigments and the thioindigo pigments contains, has.

A lamp with such a lamp has a long lifespan. It is caused by UV light, Moisture and road salt are not attacked and are resistant to temperatures between 250 and 350 ° C. Colored lights with bulb coatings with these pigments alone or together with other pigments for color correction Color standards for automotive lights, such as those for Europe by the E.C.E. and for USA by the S.A.E. are defined.

According to a preferred embodiment, the first pigment-containing layer additionally contains an iron oxide pigment. An iron oxide pigment in the layer corrects the color value the organic pigment, for example in the bluish area, e.g. from yellow to amber or from orange-red to red. In the event that the lamp in the lamp exposed to temperatures above 250 ° C for a long time, this lamp still has emergency running properties.

It may be preferred that the first pigment-containing layer is an iron oxide pigment and contains a silicon-oxygen compound. Such a layer adheres very well the glass of the lamp bulb.

According to a further preferred embodiment of the invention is between the piston and a second pigment-containing layer is arranged on the first pigment-containing layer, which contains an iron oxide pigment. If the lamp is too strong and too frequent This embodiment is also exposed to changes in temperature and the top layer flakes off the emergency running properties of the lamp.

There can be a transparent layer between the piston and the first pigment-containing layer Layer containing a silicon-oxygen compound can be arranged. This will increases the mechanical strength of the coating structure.

It is also possible that the lamp has a transparent cover layer, which is a silicon-oxygen compound contains, has to the scratch resistance of the pigmented coating to increase

The invention also relates to a lamp with a bulb with a coating a layer containing a pigment selected from the group of perylene pigments, perinone pigments, Contains isoindoline pigments and the thioindigo pigments.

In the following, the invention is explained on the basis of three exemplary embodiments.

A colored lamp according to the invention is with a lamp and a lamp cover equipped in which the lamp has a bulb with a coating of a Layer containing a pigment selected from the group of perylene pigments, perinone pigments, Has isoindoline pigments and which contains thioindigo pigments.

Depending on the design of the lamp, the coating on one or more walls of the Lamp bulb - both on the outside and on the inside of the bulb - attached his.

The colored lamp can still be used with other components, e.g. Attachment means the lamp in the lamp, means of protection against dust, damage and Moisture and the components necessary for energy supply, e.g. Versions, Lines, ballasts, starters, ignition devices and connecting terminals equipped his. A desired light distribution and glare limitation can be achieved by optical reflectors, clear or cloudy cover trays, grid made of metal or plastic, Scatter glasses and prism reflectors can be achieved. According to one embodiment the invention comprises the lamp two or more colored lamps under a common Luminaire cover that is colorless or neutral colored.

Perylene, perinone, isoindoline or thioindigo pigments are used for the first pigment-containing layer on the flask. The pigments used are polycyclic Pigments that have long been known for dyeing textile fibers. The pigments are subsequently based on their chemical constitution or the Color Index (C.I.), by the Society of Dyers and Colorists together with the American Association of Textile Chemists and Colorists is published.

Perinones [CAS4424-06-0 (trans-Perinon), CAS 4216-02-8 (cis-Perinon)) are derivatives the 1,4,5,8-naphthaline tetracarboxylic acid. Cis and trans perinone are obtained as a cis / trans isomer mixture by heating 1,4,5,8-naphthalene tetracarboxylic acid in the form of the Monoanhydrides, e.g. in glacial acetic acid at 120 ° C, with o-phenylenediamine. If you look at the isomers separates, the trans-perinone is obtained with a pure orange-yellow color and the cis-perinon with red hue.

The perylene pigments are derivatives of 3,4,9,10-perylenetetracarboxylic acid. Prefers the red yellow or red pigments perylene tetracarboxylic acid bis (methylimide) can be used PR 179 (CAS 5521-31-3), perylene tetracarboxylic dianhydride PR 224 (CAS 3049-71-6), bis-dimethylphenylperylimide PR 149 and perylenetetracarboxylic acid diimide) PV 29 (CAS 81-33-4). In general, the perylene pigments are made from 3,4,9,10-perylenetetracarboxylic anhydride by reaction with primary aliphatic amines or substituted anilines, optionally in the presence of a catalyst.

The central structural element of the isoindoline pigments is an isoindoline ring, which can be substituted with various substituents via a C = C double bond. Depending on the substituent, the isoindoline pigments are colored yellow, orange or red. PY 139 (CAS 36888-99-0) with the summation formula C ₁₆ H ₉ N ₅ O ₆ has an orange color and is very thermally stable. PY 185 (CAS 76199-85-4) has a yellow color and is also very good thermal resistance.

The thioindigo pigments are especially those with chlorine and / or with methyl groups substituted derivatives suitable for the invention. Tetrachlorothioindigo PR 88 (CAS 14295-43-3) has a red-violet color, which is used to adjust other red pigments suitable is.

The perylene, perinone, isoindoline or thioindigo pigments are preferred in finely divided, colloidal shape with a grain size of 2nm <d <200 nm used to make transparent To get layers.

According to a preferred embodiment of the invention, the first pigment-containing Layer in addition to the perylene, perinone, isoindoline and thioindigo pigments contain an iron oxide pigment.

Iron oxide pigments have a wide range of colors from yellow to orange to red, brown and black. The natural and synthetic iron oxide pigments used consist of well-defined compounds with a known crystal structure. α-Fe ₂ O ₃ (hematite) with corundum structure changes its color with particle size and crystal form from light red to dark violet. γ-Fe ₂ O, (maghemite) with a spinel structure is colored brown. α-FeOOH (goethite) with a diasporic structure changes its color with increasing particle size from light yellow to brownish yellow. γ-FeOOH (lepidocrocite) with a boehmite structure changes its color from yellow to orange with increasing particle size. These iron oxides are iron (III) oxides. The red-violet to black Fe ₃ O ₄ (magnetite) with spinel structure is only suitable in exceptional cases. The transparent iron oxide pigments are preferably used in finely divided, colloidal form with a grain size of 2 <d <15 nm in order to obtain transparent layers.

Transparent yellow iron oxide CI PY 42: 77492 is α-FeOOH (goethite) with a diasporic structure. When heated, it changes into the preferred transparent brown-red α-Fe ₂ O ₃ (hematite) CI PR 101: 77491. Orange nuances develop with a shorter temperature treatment. They can also be obtained by mixing yellow and red pigments. The iron oxide pigments with a grain size of 2 nm <d <200 nm are preferred.

It is also possible for the first pigment-containing layer to be a silicon-oxygen compound contains, e.g. amorphous or crystalline silicon dioxide, quartz, a silica gel or a Silica or a silicate, i.e. Salts or esters of silicas, especially tetraethyl orthosilicate (TEOS), a silicone or a siloxane.

The pigments and the silicon-oxygen compounds can be in a single color layer be applied.

According to another embodiment of the invention, the colored piston coating also have a variable multilayer structure. It always includes a first colored layer, which is a pigment selected from the group of perylene pigments, perinone pigments, isoindoline pigments and which contains thioindigo pigments.

Under the first colored layer, a layer containing iron oxide can first be placed on the Lamp bulb be applied. The iron oxide-containing layer can either be the iron oxide contained as a finely divided pigment or as a precipitate from a sol-gel process. When the iron oxide is applied as a pigment, it comes as a manufacturing process both a dry, e.g. electrostatic deposition, as well as wet application, e.g. as an aqueous suspension - by dipping or spraying.

In another embodiment of the invention, the multilayer structure for the coating of the lamp bulb is such that an iron oxide-containing layer is first applied to the inside or outside of the lamp bulb. For this layer, the iron oxide can be applied either as a fine pigment or in a sol-gel process. A temperature-resistant, transparent protective layer which contains a silicon-oxygen compound, for example an SiO ₂ or a quartz glass layer, is applied over the layer containing iron oxide. The pigment-containing layer is in turn applied to this.

In a further embodiment of the invention, the multi-layer structure for the Coating the lamp bulb so that between the bulb and the first pigmented Layer a transparent layer that contains a silicon-oxygen compound contains, is arranged.

A temperature-resistant, transparent cover layer can be arranged over the pigment-containing layers. The cover layer contains a silicon-oxygen compound, for example amorphous or crystalline silicon dioxide, quartz, a silica gel or a silica or a silicate, ie salts or esters of silica, in particular tetraethylorthosilcat (TEOS). Alternatively, this additional top layer can also be a temperature-resistant, transparent, colorless or dye-containing lacquer or a transparent ceramic layer, for example made of Al ₂ O ₃ or enamel. If the coatings are applied to the inside of the flask, the top layer prevents chemical changes in the pigments. If the coating is applied on the outside, the cover layer forms a scratch-resistant surface, which facilitates further processing of the bulb in lamp production.

A cover layer with a suitable refractive index is preferably used, which has the Scattering of the pigment-containing layers is reduced.

As a method for applying the coating on the lamp bulb, conventional Processes for coating complex shaped substrates can be used. These include the wet coating processes such as Spraying, dipping and brushing on. Dry coating processes, e.g. electrostatically assisted dusting are suitable for applying the pigment-containing coating to the lamp bulb.

For wet coating processes, the pigments must be dispersed in water, an organic solvent or a binder preparation, optionally together with a dispersant, a surfactant and an antifoam. Suitable for binder preparations for a lamp according to the invention are organic or inorganic binders which can withstand an operating temperature of 250 ° C to 350 ° C without decomposition, embrittlement or discoloration.
For binder-free, pigment-containing layers, a layer thickness of 0.5 to 2.0 µm can be sufficient. Binder-containing layers generally have a layer thickness of 1 to 50 μm.
The pigment coated lamps were subjected to an accelerated thermal stress test in which the lamps were kept at 300 ° C permanently. The color location changed only minimally within a period of 150 hours within the range specified by the ECE and the SAE for the color specification. Even with regular lamp operation over a period of 500 h, the color point remained within the ECE color specification.

Embodiment 1

A very suitable iron oxide pigment is hematite. A coating is obtained in particular together with a mixture. which has a very good color point saturation in the red area and good light transmission.
To produce the piston coating, a dispersion of 7.5% by weight cis / trans-perinone pigment VR 54 and 7.5% by weight transparent iron oxide pigment PR 101, 0.75% by weight sodium polyacrylate as a dispersant, 0.075% by weight polyethylene propylene oxide as anti-foaming agent wet-ground with water in an agitator mill until the agglomerated pigment is dispersed. A surfactant, for example a polyether-modified polysiloxane, can also be added to the dispersion. The cleaned and heated lamp bulbs are immersed in this dispersion and then baked at 250 ° C.
180 g of tetraethyl orthosilicate are mixed with 2077 g of ethanol, 146 g in hydrochloric acid and 27 ml of an anionic surfactant. The pre-coated lamp bulbs are dipped into this mixture and briefly heated at 300 ° C in order to convert tetraethyl orthosilicate into a silicon dioxide layer.

Embodiment 2

A very suitable iron oxide pigment is hematite. In particular with an organic red pigment, which is applied as the first layer in a temperature-resistant silicone resin, a coating is obtained which has very good color point saturation in the red area and good light transmission.
To produce the lamp coating, a dispersion of 15% by weight of transparent iron oxide pigment PR 101, 3% by weight of a 25% solution of sodium in a polycarboxylic acid as a dispersing agent, 0.075% by weight of potyethylene propylene oxide as an anti-foaming agent is first wet with water in a stirred mill milled until the agglomerated pigment is dispersed. The dispersion is filtered to remove contaminants and hard agglomerates. For better wetting of the lamp bulb, a surfactant, for example a polyether-modified polysiloxane, is added. The dispersion is diluted to a pigment concentration of 8.7% by weight. The cleaned and heated lamp bulbs are immersed in this dispersion, dried and then baked at 450 ° C. A transparent hematite layer approximately 0.5 µm thick is obtained.

Another pigment dispersion is obtained by grinding the organic red pigment Dimethylperylimide PR 179 in a ball mill. 6% by weight of pigment in one Solvent mixture of xylene and cyclohexanone (ratio 5: 1) with the addition of a Dispersing agent ground until the pigment agglomerates are dispersed. As a dispersant a pigment-affine block copolymer in a concentration of 18% by weight based on the amount of pigment used. The dispersion is filtered and with a Siliconhar solution mixed. The silicone resin is a reactive phenyl-methyl silicone that is thermally cross-linked and then stable up to temperatures of 500 ° C. The silicone resin solution has a polymer content of 50% by weight in a solvent mixture like this has already been used to grind the pigment. The ready-to-use mixture contains 32% by weight silicone and 12% by weight dimethylperylimide pigment PR 179. The already Lamp droppings covered with a hematite layer are sprayed with the pigment containing dimethylperylimide Silicone resin solution covered. The solvent is evaporated and crosslinked the silicone resin at 250 ° C. A red, 8 to 10 μm thick silicone resin layer is obtained as the outer cover layer of the lamp. The two-layer hematite coating and dimethylperylimide PR 179 results in a transparent red coating on the lamp, which complies with the ECE and SAE standards for red signal lamps.

Embodiment 3

A very suitable iron oxide pigment is hematite. In particular with an organic yellow pigment, which is applied as the first layer in a temperature-resistant silicone resin, a coating is obtained which has very good color point saturation in the amber area and good light transmission.
The hematite layer to be applied first to the lamp bulb is obtained by grinding the iron oxide pigment PR101 in water as described in Example 2. The ground hematite dispersion is diluted to 5.5% by weight of pigment. The lamp bulb is coated by dipping. The dried and baked hematite layer at 450 ° C has a thickness of 0.3 µm. The layer is transparent and colored red-brown. The color point does not yet meet the ECE standard for amber-colored signal lamps. Therefore, a further coating with a suitable yellow pigment is necessary to make a color point correction in accordance with the ECE standard.
The isoindoline pigment PY 139 is ground in a solvent mixture with the addition of a pigment-affine block copolymer as a dispersant. The grinding is carried out according to the method given in Example 2 for the dimethylperylimide pigment. The yellow pigment dispersion and the silicone resin solution described in working example 2 are mixed in a ratio. that the concentration of isoindoline yellow pigment is 1.6% by weight and that of silicone is 35% by weight. The lamp bulb, which is already covered with a hematite layer, is covered by spraying with the silicone resin solution containing isoindoline pigment. The solvent is evaporated and the silicone mixture is crosslinked at 250 ° C. An approximately 10-15 µm thick transparent yellow silicone resin coating is obtained on the hematite-coated lamp, which shifts the color point of the lamp into the ECE standard range for amber-colored signal lamps.

Embodiment 4

A very suitable mixture of two organic pigments is the use of an organic red pigment (PR 149, bis-dimethylphenylperylimide) and an organic yellow pigment (PY139, isoindoline yellow pigment) in a silicone resin. A coating is obtained which has very good color point saturation in the amber region and good light transmission.
The yellow isoindoline pigment PY 139 is ground in a solvent mixture with the addition of a pigment-affine block copolymer as a dispersant. The grinding is carried out according to the method given in Example 2 for the dimethylperylimide pigment. The yellow pigment dispersion and a 50% by weight silicone resin solution, which is a mixture of 80 parts of reactive methylphenyl silicone and 20 parts of reactive polyester-modified methylphenyl silicone, are mixed in a ratio such that the concentration of isoindoline yellow pigment 2.4 % By weight and 35% by weight of silicone.
The red bis-dimethylphenylperylimide pigment PR149 is ground in a solvent mixture with the addition of a pigment-affine block copolymer as a dispersant. The grinding is carried out according to the method given in Example 2 for the dimethylperylimide pigment. The red pigment dispersion and a 50% by weight silicone resin solution, which is a mixture of 80 parts of reactive methyl-phenyl silicone and 20 parts of reactive polyester-modified methyl-phenyl silicone, are mixed in a ratio such that the concentration of red bis-dimethylphenylperylimide Pigment is 0.8% by weight and 35% by weight of silicone.
The two pigment dispersions are mixed in equal proportions and applied to the lamp bulb by spraying. The solvent is evaporated and the silicone resin crosslinked at 250 ° C. A transparent, amber-colored silicone resin layer with a thickness of 10 to 15 µm is obtained, which corresponds to the ECE standard for signal lamps.

Embodiment 5

A coating is obtained which has very good color point saturation in the red color range and good light transmission when the organic red pigment bis-dimethylphenylperylimide pigment PR149 is used in a silicone resin.
The red bis-dimethylphenylperylimide pigment PR149 is ground in a solvent mixture with the addition of a pigment-affine block copolymer as a dispersant. The grinding is carried out according to the method given in Example 2 for the dimethylperylimide pigment. The red pigment dispersion and a 50% by weight silicone resin solution are mixed in a ratio such that the concentration of red bisdimethylphenylperylimide pigment is 2.9% by weight and that of silicone 33% by weight. The silicone resin is a reactive phenyl-methyl silicone that is thermally cross-linked and then stable up to temperatures of 500 ° C.
The lamp bulb is sprayed with the red, pigment-containing silicone resin solution. The solvent is evaporated and the silicone resin crosslinked at 250 ° C. An approximately 15 µm thick transparent red silicone resin coating is obtained which has a color point which corresponds to the ECE and SAE standards for red signal lamps.

Embodiment 6

A particularly hard and scratch-resistant coating is obtained which has a very good color saturation in the red color range and good light transmission if a layer of the organic red pigment bis-dimethylphenylperylimide PR149 is covered with a silicon dioxide sol-gel layer.
To produce the lamp coating, a dispersion of 10% by weight bis-dimethylphenylperylimide PR14), 10% by weight of a 40% aqueous solution of a pigment-affine block copolymer as a dispersant, 0.075% by weight polyethylene propylene oxide as an antifoam with water in a ball mill is first used milled until the agglomerated pigment is dispersed. The dispersion is filtered to remove contaminants and hard agglomerates. A surfactant, for example a polyether-modified polysiloxane, can be added to improve the wetting of the lamp bulb.
The cleaned and heated lamp bulbs are immersed in this dispersion, dried and then baked at 250 ° C. A transparent pigment layer approximately 1.5 μm thick is obtained.
180 g of tetraethyl orthosilicate are mixed with 2077 g of ethanol, 146 g in hydrochloric acid and 27 ml of an anionic surfactant. The pre-coated lamp bulbs are dipped into this mixture and briefly heated at 300 ° C in order to convert tetraethyl orthosilicate into a silicon dioxide layer. A scratch-resistant, transparent red coating is obtained which has a color point which corresponds to the ECE and SAE standards for red signal lamps.

Exemplary embodiment 7

A coating is obtained which has very good color point saturation in the red area and good light transmission if a mixture of the very suitable iron oxide pigment hematite with the organic red pigment dimethylperylimide PR179 is used.
A pigment dispersion of the organic red pigment dimethylperylimide PR 179 is obtained by grinding in a ball mill. For this purpose, 6% by weight of pigment is ground in a solvent mixture of xylene and cyclohexanone (ratio 5: 1) with the addition of a dispersant until the pigment agglomerates are dispersed. A pigment-affine block copolymer in a concentration of 18% by weight, based on the amount of pigment, is used as the dispersant.
A further pigment dispersion is obtained by grinding iron oxide pigment PR 101. 15% by weight of transparent iron oxide pigment PR 101 and 3.75% by weight of a pigment-affine block copolymer are used as dispersants in a 25% by weight solution of a phenylmethyl silicone resin ground in a ball mill. The solvent is a mixture of xylene and cyclohexanone (ratio 5: 1). The silicone resin is a reactive phenyl-methyl silicone that is thermally cross-linked and then stable up to temperatures of 500 ° C.
The pigment dispersions are filtered to remove contaminants and hard agglomerates and mixed with a silicone resin solution. The silicone resin is a reactive phenyl-methyl silicone that is thermally cross-linked and then stable up to temperatures of 500 ° C. The mixture suitable for spray coating contains 42% by weight of silicone, 2.2% by weight of dimethylperylimide pigment and 2.8% by weight of iron oxide pigment PR 101.
The lamp bulb is sprayed with the red, pigment-containing silicone resin solution. The solvent is evaporated and the silicone resin crosslinked at 250 ° C. An approximately 15 to 20 μm thick transparent red silicone resin coating is obtained which has a color point which corresponds to the ECE and SAE standards for red signal lamps.

Embodiment 8

A coating is obtained which has very good color point saturation in the red area and good light transmission if a mixture of the very suitable transparent iron oxide pigment Hematite PR101 with the isoindoline yellow pigment PY139 is used.
15% by weight of transparent iron oxide pigment PR 101 and 3.75% by weight of a pigment-affine block copolymer as a dispersant are ground in a 25% by weight solution of a phenyl-methyl-silicone resin in a ball mill. The solvent is a mixture of xylene and cyclohexanone (ratio 5: 1). The silicone resin is a reactive phenyl-methyl silicone that is thermally cross-linked and then stable up to temperatures of 500 ° C.
Another pigment dispersion is obtained by grinding a yellow isoindoline pigment, PY 139, in a ball mill. For this purpose, 6% by weight of pigment is ground in a solvent mixture of xylene and cyclohexanone (ratio 5: 1) with the addition of a dispersant until the pigment agglomerates have been dispersed. A pigment-affine block copolymer in a concentration of 18% by weight, based on the amount of pigment, is used as the dispersant.
The dispersions are filtered and mixed with a silicone resin solution. The silicone resin is a reactive phenyl-methyl silicone, which is dissolved in a solvent mixture of xylene and cyclohexanone (ratio 5: 1). The mixture suitable for spray coating contains 35% by weight of silicone, 2.8% by weight of iron oxide pigment PR 101 and 1.6% by weight of isoindoline yellow pigment PY 139.
The lamp bulb is spray-coated with the pigment-containing silicone resin solution. The solvent is evaporated and the silicone resin crosslinked at 250 ° C. A transparent, amber-colored silicone resin layer approximately 15 µm thick is obtained, which corresponds to the ECE standard for signal lamps.

Embodiment 9

A coating is obtained which has very good color saturation in the amber color range and good Lichuransmission when using the organic isoindoline yellow pigment PY185.
The yellow isoindoline pigment PY185 is ground in a solvent mixture with the addition of a pigment-affine block copolymer as a dispersant. The grinding is carried out according to the method given in Example 2 for the dimethylperylimide pigment. The yellow pigment dispersion and a 50% by weight silicone resin solution are mixed in a ratio such that the concentration of yellow isoindoline pigment is 2.9% by weight and that of silicone 33% by weight. The silicone resin is a reactive phenyl-methyl silicone that is thermally cross-linked and then stable up to temperatures of 500 ° C.

The lamp bulb is sprayed with the yellow, pigment-containing silicone resin solution covered. The solvent is evaporated and the silicone resin crosslinked at 250 ° C. An approximately 20 μm thick transparent yellow coating is obtained which has a color point which complies with the ECE and SAE standards for amber-colored signal lamps.

Embodiment 10

A coating is obtained which has very good color point saturation in the red color range and good light transmission when using the red pigment dichlorodiketopyrrolo-pyrrole PR254.
The red pigment dichloro-diketopyrrolo-pyrrole (PR254) is ground in a solvent mixture with the addition of a pigment-affine block copolymer as a dispersant. The grinding is carried out according to the method specified in Example 5. The red pigment dispersion and a 50% by weight silicone resin solution are mixed in a ratio such that the concentration of red dichloro-diketopyrrolo-pyrrole pigment is 2.9% by weight and that of silicone is 33% by weight. The silicone resin is a reactive phenyl-methyl silicone that is thermally cross-linked and then stable up to temperatures of 500 ° C. The lamp bulb is sprayed with the red, pigment-containing silicone resin solution. The solvent is evaporated and the silicone resin crosslinked at 250 ° C. An approximately 15 to 20 µm thick transparent red coating is obtained, which has a color point which corresponds to the ECE and SAE standards for red signal lamps.

Embodiment 11

A coating is obtained which has very good color point saturation in the red area and good light transmission when a mixture of the very suitable iron oxide pigment Hematite PR101 with the organic red pigment tetrachlorothioindigo PR88 is used.
A pigment dispersion of the organic red pigment tetrachlorothioindigo PR88 is obtained by grinding in a ball mill. For this purpose, 8.5% by weight of pigment is ground in a solvent mixture of xylene and cyclohexanone (ratio 5: 1) with the addition of a dispersant until the pigment agglomerates are dispersed. A pigment-affine block copolymer in a concentration of 15% by weight, based on the amount of pigment, is used as the dispersant.
A further pigment dispersion is obtained by grinding iron oxide pigment PR 101. 15% by weight of transparent iron oxide pigment PR 101 and 3.75% by weight of a pigment-affine block copolymer are used as dispersing agents in a 25% by weight solution of a phenyl-methyl-silicone resin in one Ball mill ground. The solvent is a mixture of xylene and cyclohexanone (ratio 5: 1). The silicone resin is a reactive phenyl-methyl silicone that is thermally cross-linked and then stable up to temperatures of 500 ° C.
The pigment dispersions are filtered to remove contaminants and hard agglomerates and mixed with a silicone resin solution. The silicone resin is a reactive phenyl-methyl silicone that is thermally cross-linked and then stable up to temperatures of 500 ° C. The mixture suitable for spray coating contains 37% by weight of silicone, 3.2% by weight of tetrachlorothioindigo PR88 and 2.8% by weight of iron oxide pigment PR 101.
The lamp bulb is sprayed with the red, pig-containing silicone resin solution. The solvent is evaporated and the silicone resin crosslinked at 250 ° C. An approximately 15 µm thick transparent red coating is obtained which has a color point which corresponds to the ECE and SAE standards for red signal lamps.

Claims (7)

Colored lamp, equipped with a lamp and a lamp cover in which the Lamp a bulb with a coating with a first pigmented layer that a pigment selected from the group of perylene pigments, perinone pigments, isoindoline pigments and which contains thioindigo pigments. Colored lamp according to claim 1,
characterized,
that the first pigment-containing layer additionally contains an iron oxide pigment. Colored lamp according to claim 1,
characterized,
that the first pigment-containing layer contains an iron oxide pigment and a silicon-oxygen compound. Colored lamp according to claim 1,
characterized,
that a second pigment-containing layer is arranged between the piston and the first pigment-containing layer, which contains an iron oxide pigment. Colored lamp according to claim 1,
characterized,
that a transparent layer containing a silicon-oxygen compound is arranged between the piston and the first pigment-containing layer. Colored lamp according to claim 1,
characterized,
that the lamp has a transparent cover layer containing a silicon-oxygen compound. Lamp with a bulb with a pigmented coating that selected a pigment from the group of perylene pigments, perinone pigments, isoindoline pigments and which contains thioindigo pigments.