Electric lamp and discharge devices – With gas or vapor – Envelope with particular structure
Reexamination Certificate
2000-09-07
2004-11-16
Williams, Joseph (Department: 2879)
Electric lamp and discharge devices
With gas or vapor
Envelope with particular structure
C313S112000
Reexamination Certificate
active
06819049
ABSTRACT:
BACKGROUND OF THE INVENTION
1. The Field of the Invention
The invention generally relates to an electric lamp. The invention specifically relates to a light-transmitting lamp vessel, which accommodates a light source for emitting a visible light and has a light-absorbing coating for absorbing part of the visible light.
2. Description of the Related Art
Such electric lamps are predominantly used as indicator lamps in vehicles, for example as an amber-colored light source in indicators or as a red-colored light source in brake lights of automobiles. Alternative embodiments of such lamps, wherein the color temperature is increased by a light-absorbing coating, can also be used as headlamps of a vehicle. The light-absorbing coatings are also used as a color layer on (incandescent) lamps for general lighting purposes. The electric lamps can also be used in traffic lights.
A known electric lamp disclosed in Canadian Patent No. CA-A 0 766 196 has a coating applied to the lamp vessel, which coating comprises a substance which absorbs visible light, for example a dye and/or a pigment.
For the application of the coatings, use is generally made of organic lacquers. The organic lacquer forms a kind of carrier matrix containing the pigment or the dye. The organic lacquer enables, inter alia, a good adhesion of the coating to the lamp vessel to be obtained. In the known lamp, use is made of a polymethylmethacrylate polymer, which is applied to the lamp vessel by a dip coating. In an alternative embodiment, a lacquer of a polyester silicone is applied to the lamp vessel by a spraying process. Moreover, use is often made of organic dyes, such as a dye called Zapon 157. Such dyes are added to the lacquer layer to obtain the desired color point.
It is a drawback of the known electric lamp comprising a light-absorbing coating on the basis of an organic lacquer that the adhesion of the coating to the lamp vessel deteriorates substantially and/or the organic dye degrades at temperatures above approximately 220° C. At temperatures close to or higher than the temperature, there is an increased risk that the coating cracks and/or becomes detached from the lamp vessel. Since the dimensions of the luminaires accommodating the electric lamp decrease continuously as do the dimensions of the electric lamp itself, the temperature of the lamp vessel provided with the coating currently reaches a temperature of 250° C. In addition, there is a trend towards further miniaturization, so that the lamp vessel provided with the light-absorbing coating reaches temperatures of approximately 325° C.
SUMMARY OF THE INVENTION
It is an object of the invention to provide an electric lamp to address the above drawbacks of the prior art.
In accordance with the invention, an electric lamp is characterized in that a light-absorbing coating comprises a network which can be obtained by conversion of an organically modified silane by a sol-gel process, and the organically modified silane is selected from the group formed by compounds of the following structural formula: R′Si(OR″)
3
, wherein R′ comprises an alkyl group or an aryl group, and wherein R″ comprises an alkyl group.
By replacing the organic lacquer in the light-absorbing layer in the known electric lamp by a network comprising an organically modified silane as the starting material, an optically transparent, non-scattering, light-absorbing coating is obtained which can resist temperatures up to 400° C. By using an organically modified silane in the manufacture of the network, a part of the R′ groups, i.e. the alkyl or aryl groups, remain present as an end group in the network. As a result, instead of four network bonds per Si atom, the network in accordance with the invention has fewer than four network bonds per Si atom. This results, by way of example, in a network comprising, on average, approximately three network bonds per Si atom. Despite the fact that the network is partly composed of the alkyl or aryl groups, a network is obtained whose density is at least substantially equal to that of the customary silica network. Unlike the customarily used silica network, a network which is partly composed of the alkyl or aryl groups has a greater elasticity and flexibility. This enables relatively thick light-absorbing coatings to be manufactured.
Preferably, the R′ group comprises CH
3
or C
6
H
5
. These substances have a relatively good thermal stability. A network comprising methyl or phenyl groups enables thicker coatings to be obtained. Experiments have further shown that coatings wherein methyl or phenyl groups are incorporated in a network are stable up to a temperature of at least 350° C. the groups are end groups in the network and remain part of the network at the higher temperatures. At such a relatively high temperature load on the light-absorbing coating, no appreciable degradation of the network occurs during the service life of the electric lamp.
Preferably, the R″ group comprises CH
3
or C
2
H
5
. Methyl and ethyl groups are particularly suitable because methanol and ethanol are formed in the hydrolysis process, which substances are compatible with the pigment dispersion and evaporate relatively easily. In general, the methoxy groups (—OCH
3
) react more rapidly than the ethoxy groups (—OC
2
H
5
) which, in turn, react more rapidly than (iso)propoxy groups (—OC
3
H
7
). For a smooth hydrolysis process, use is advantageously made of R″ groups which are not very long.
Very suitable starting materials for the manufacture of the network in accordance with the invention are (1) methyltrimethoxy silane (MTMS), where R′=R″=CH
3
, (2) methyltriethoxy silane (MTES), where R′=CH
3
and R″=C
2
H
5
, (3) phenyltrimethoxy silane (PTMS), where R′=C
6
H
5
and R″=CH
3
, and
(4) phenyltriethoxy silane (PTES), where R′=C
6
H
5
and R″=C
2
H
5
. Such starting materials are known per se and commercially available.
An embodiment of the electric lamp in accordance with the invention is characterized in that the thickness t
c
of the light-absorbing coating is t
c
≧1 &mgr;m. If use is made of a network composed of silica, which comprises four network bonds per Si atom, the thickness of the coating is limited, under atmospheric conditions, to approximately at most 0.5 &mgr;m. In such silica layers whose thickness exceeds the thickness, stress in the layer readily leads to cracks and/or the coating readily becomes detached from the lamp vessel. By using a network comprising fewer than four network bonds per Si atom, a much thicker layer thickness can be attained. Preferably, t
c
≧2 &mgr;m. In thicker, light-absorbing coatings, more pigment or dye can be incorporated, whereby the color effect of the coating is improved.
Inorganic filling materials may be incorporated in the light-absorbing coating. For this purpose, in a favorable embodiment of the electric lamp in accordance with the invention, silica particles having a diameter d≧50 nm are incorporated in the network. Incorporation of these so-called nano-sized silica particles reduces shrinkage of the layer during the manufacture thereof. In addition, the incorporation of the nano-sized silica particles makes it possible to obtain even thicker coatings which bond well to the lamp vessel. By adding nano-sized silica particles to a network, wherein alkyl or aryl groups, which form the R′ groups, are present as the end group, 20 &mgr;m thick layers having favorable bonding properties can be obtained. Such thick layers can contain considerable quantities of a pigment or a dye to obtain the desired color point of the light-absorbing coating. By incorporating the silica particles it becomes possible to manufacture light-absorbing coatings in a larger thickness. The refractive index of such a coating is less influenced by the refractive index of the pigment when the same quantity of pigment is incorporated in a thicker coating. The use of the silica particles thus res
Bohmer Marcel René
Broersma Remy Cyrille
Keursten Theodora Antonia Petra Maria
Neilen-Ten Wolde Paulina Maria Christina
Snijkers-Hendrickx Ingrid Jozef Maria
Koninklijke Philips Electronics , N.V.
Williams Joseph
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