The invention relates to a high pressure gas discharge lamp comprising a ceramic discharge vessel having a container wall enclosing a discharge space having a filling, further comprising a first and a second electrode, mutually oppositely arranged in the discharge space and defining a length axis of the discharge vessel, still further comprising a first and a second feedthrough, both extending in a gas-tightly sealed manner through the container wall and on which feedthroughs a respective electrode is mounted, and further comprising a UV-enhancer.
The invention further relates to a method of manufacture of said electric lamp.
A lamp of the type mentioned in the opening paragraph is known from U.S. Pat. No. 5,811,933. The known lamp is a high-pressure discharge lamp, more in particular a metal halide lamp. Such a lamp is suitable for various applications such as general interior lighting, general exterior lighting, video illumination, etc. The discharge vessel of the known lamp is made of ceramic material and is often obtained, via an extrusion process, in a tubular shape and subsequently provided with end plugs/end parts. Alternatively a slip-casting process or an injection molding process is used to manufacture the discharge vessel with end parts. Ceramic material in the present description and claims is understood to be a densely sintered polycrystalline metal oxide such as, for example, Al2O3 or YAG, and densely sintered polycrystalline metal nitride such as, for example, AlN.
A known problem of this type of lamp is the comparatively wide spread in ignition time. This points to a shortage of free electrons during lamp ignition. The addition of a small quantity of 85Kr in the discharge vessel can supplement such a shortage. A disadvantage of this, however, is that 85Kr is radioactive. Efforts have been made to avoid this through the use of a UV-enhancer, which is a small UV discharge tube positioned adjacent the discharge vessel and acting as a UV source. The UV-enhancer in the known lamp is formed by a UV-transmitting ceramic tube positioned parallel to and at a distance from the discharge vessel. Upon breakdown, the UV-enhancer will generate said UV-radiation. The influence of this UV-radiation leads to the production of free electrons in the discharge vessel, which in turn strongly promote lamp ignition. Disadvantages of the known lamp are the relatively complicated construction, and the relatively cumbersome manufacture process which, in addition, is relatively expensive.
It is an object of the invention to provide a lamp in which at least one of the abovementioned disadvantages is counteracted. According to the invention, a lamp of the kind as described in the opening paragraph has a UV-enhancer with a wall portion and a chamber, said chamber being enclosed by the wall portion of the UV-enhancer and an end part of the container wall. It is thus attained that the UV-enhancer is directly adjacent to the discharge vessel, whereby its functioning as a fast and reliable ignition aid is improved. Furthermore, a relatively compact, readily manufacturable lamp is obtained in which the number of components is reduced as, contrary to the known lamp, no complex, separate mounting construction for the UV-enhancer is required and the container wall of the discharge vessel simultaneously functions as a wall of the UV-enhancer. The UV-enhancer has a wall which is made from densely sintered polycrystalline Al2O3. The fact that this is widely used as a wall material for high-pressure discharge lamps has the major practical advantage that an existing technology for ceramic discharge vessels can be utilized. A very high degree of miniaturization is possible here. Although it was found that a combination of a rare gas and Hg is suitable as a filling, the UV-enhancer preferably has a rare gas filling. A suitable rare gas is inter alia Ne. Ar was found to be particularly suitable as a filling. A pressure (filling pressure) is preferably chosen for the filling which accompanies a minimum breakdown voltage. This filling pressure may be readily ascertained experimentally. A fair approximation can be realized by means of the Paschen curve. A mixture of rare gases in the form of a Penning mixture is also suitable.
An embodiment of the high pressure gas discharge lamp is characterized in that one of the feedthroughs forms an internal electrode of the UV-enhancer, said internal electrode extending through the chamber and extending in a gas-tightly sealed manner through said wall portion. Thus, compared to the known lamp, a further reduction in the number of components is attained, as the separate feedthrough and the internal electrode in the known lamp are combined into one part.
An embodiment of the high pressure gas discharge lamp is characterized in that the UV-enhancer is tubular and concentric with the longitudinal axis extending through the UV-enhancer. This has the advantage that, compared to the known lamp, the manufacture of a rotationally symmetric discharge vessel with UV-enhancer and hence a simpler manufacture process of the lamp is enabled. One way to further simplify the manufacture process is to separate the feedthrough that is (to be) located at the side of the UV-enhancer into a first part sealed in the end part and a second part sealed in the wall portion, the first part in electrically conductive contact with the second part once the lamp is fully assembled. The separation into two parts enables separate, simple, dedicated processing of the sealing parts without the necessity to take precautions to counteract mutual detrimental effects on the sealing quality of the respective dedicated sealing processes. In particular the dedicated process for the manufacture of the discharge vessel comprises shrink-sinter sealing of the discharge vessel under vacuum or Hydrogen atmosphere to at least 98% density to obtain a gastight, relatively clear discharge vessel. The dedicated process for the UV-enhancer comprises a pre-sinter shrink-sealing process to about 60% density under an inert (non-corrosive/oxidative) atmosphere, the wall-portion of the UV-enhancer still having a porous structure, which pores are still accessible for ambient gases. Moreover, said separation into two parts enables an embodiment of the high pressure gas discharge lamp which is characterized in that said electrically conductive contact between the first part and the second part is free from a weld. Such an electrically conductive contact without a weld is obtainable as follows:
the discharge vessel, which has a relatively clear container wall which is fully sintered to at least 98% density, and the UV-enhancer, of which the wall portion is pre-sintered to only about 60% density are assembled together, taking care that the first part of the feedthrough in the discharge vessel and the second part of the feedthrough in the UV-enhancer are such that said first and second part abut or substantially abut each other; subsequently, the combination of fully sintered discharge vessel and pre-sintered UV-enhancer undergo a final sinter step under, for example, an Ar or N2-atmosphere, to fully, i.e. to 98% density, shrink-sinter the UV-enhancer wall-portion onto the container wall.
Said final shrink-sinter step involves four phenomena, i.e.:
the UV-enhancer shrinks in the radial direction, thereby clamping itself in a gastight manner onto the container wall, thus realizing the gastight chamber of the UV-enhancer;
the UV-enhancer shrinks in the axial direction, thereby forcing the first part and the second part of the feedthrough towards each other, thus establishing the electrically conductive contact without a weld;
the chamber of the UV-enhancer is automatically filled with the gas used during the final sinter step, i.e. with Ar or N2; a fill pressure of about 0.15 bar will be obtained inside the chamber when during the final sinter step a gas pressure of about 1 bar is applied;
due to the Ar or N2 gas atmosphere the wall portion of the UV-enhancer becomes opaque as a result of inclusions of the ambient gas during the final sinter step, which gas is trapped inside the wall portion once the final sinter step is completed. Said opaque wall portion reflects the generated UV-radiation towards and into the container wall and into the discharge space during operation of the lamp, thus inducing a fast and reliable ignition of the lamp.
An embodiment of the high pressure gas discharge lamp is characterized in that the first part is made of iridium and the second part is made of niobium. Iridium is directly sealable, i.e. without the need/use of a sealing glass/frit, into the wall of the container, thus providing a seal which is comparatively very resistant to the salt filling inside the discharge vessel. Niobium is well-known to be readily sealable in the wall portion of the UV-enhancer because its coefficient of thermal expansion excellently matches that of alumina.
An embodiment of the high pressure gas discharge lamp is characterized in that the second part comprises niobium wire having a thin-diameter part and a thick-diameter part, for example 250 μm, the niobium wire being sealed in the wall portion with its thick-diameter part. This embodiment is in particular suitable for lamps having a relatively high nominal power, for example lamps having a nominal power of at least 400 W.
An embodiment of the high pressure gas discharge lamp is characterized in that the container wall has an outer container surface and the wall portion has an outer wall surface and in that an active antenna extends over said outer container surface and said outer wall surface. In this embodiment the (electrode of the) UV-enhancer and the active antenna are mutually arranged such that a capacitive coupling between the UV-enhancer and the active antenna is achieved, thus further enabling a fast and reliable ignition of the lamp. A convenient method of providing such an active antenna on the container wall and the wall portion makes use of a printing process of, for example, a Tungsten-containing electrically conductive paste. To simplify the printing process, it is favorable when an embodiment of the high pressure gas discharge lamp is characterized in that the outer container surface is flush with the outer wall surface of the UV-enhancer.
The invention further relates to a method of manufacturing a high pressure gas discharge lamp, comprising the steps of:
manufacturing a sealed discharge vessel by providing its discharge space with a filling and first and second electrodes mounted on a respective first feedthrough part and sealing said first feedthrough parts gas-tightly in a container wall of the discharge vessel;
shrink-sintering a ceramic wall portion of a concave UV-enhancer portion to about 60% density, either simultaneously with sealing a second part of one of the feedthroughs in a ceramic wall of a concave UV-enhancer portion so as to extend therethrough, or prior to a separate sealing step of the second part of the feedthrough in the wall portion of the UV-enhancer portion, using a sealing glass;
assembling the discharge vessel and the UV-enhancer portion such that they both abut against the first feedthrough and the second feedthrough part and subsequently shrink-sintering (at about 1600° C., i.e. 1500-1700° C., and about 1 bar Argon, i.e. 0.4-2 bar Argon) under a chosen gas atmosphere the UV-enhancer part to a density of about 98% and onto the discharge vessel to form the closed wall of the gas-filled UV-enhancer and to establish a fixed electrically conductive contact of the first feedthrough with the second feedthrough part.
This method has the advantage of a relatively simple manufacture process. The separation into two parts enables separate, simple, dedicated processing of the sealing parts without the necessity to take precautions to counteract mutual detrimental effects on the sealing quality of the respective dedicated sealing processes. In particular the dedicated process for the manufacture of the discharge vessel comprises shrink-sinter sealing of the discharge vessel under vacuum or Hydrogen atmosphere to a density at which the sintered container wall material is no longer porous or permeable to gas, for example in that it has at least 90% or 98% density, to obtain a gastight, relatively clear discharge vessel. The dedicated process for the UV-enhancer comprises a pre-sinter shrink sealing process to about 60% density, i.e. 50%-65% density, under an inert (non-corrosive/oxidative) atmosphere, the wall-portion of the UV-enhancer still having a porous structure, which pores are still accessible for ambient gases. Subsequently, the combination of fully sintered discharge vessel and pre-sintered UV-enhancer undergo a final sinter step under a desired gas atmosphere, for example, an Ar or N2-atmosphere, to fully, i.e. to at least 90% or at least 98% density, shrink-sinter the UV-enhancer wall portion onto the container wall. Moreover, as already said hereinabove, said separation into two parts enables an embodiment of the high pressure gas discharge lamp which is characterized in that said electrically conductive contact between the first part and the second part is free from a weld.
Said final shrink sinter step involves three or four phenomena, i.e.:
the UV-enhancer shrinks in the radial direction, thereby clamping itself in a gastight manner onto the container wall, thus realizing the gastight chamber of the UV-enhancer;
the UV-enhancer shrinks in the axial direction, thereby forcing the first part and the second part of the feedthrough towards each other, thus establishing the electrically conductive contact without a weld;
the chamber of the UV-enhancer is automatically filled with the desired gas used during the final sinter step; a fill pressure of about 0.15 bar will be obtained inside the chamber when during the final sinter step a gas pressure of about 1 bar is applied;
in the case that use is made of an Ar and/or N2 gas atmosphere during the final sinter step, due to the Ar or N2 gas atmosphere, the wall portion of the UV-enhancer becomes opaque as a result of inclusions of the ambient gas during the final sinter step, which gas is trapped inside the wall portion once the final sinter step is completed. Said opaque wall portion reflects the generated UV-radiation towards and into the container wall and into the discharge space during operation of the lamp, thus inducing a fast and reliable ignition of the lamp.
The above and further aspects of the lamp according to the invention will be explained in more detail with reference to a drawing (not true to scale), in which:
A number of lamps having a construction as shown in
In
In
This application is the U.S. National Phase application under 35 U.S.C. §371 of International Application No. PCT/IB2013/056253, filed on Jul. 30, 2013, which claims the benefit of U.S. Provisional Patent Application No. 61/679,112, filed on Aug. 3, 2012. These applications are hereby incorporated by reference herein.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2013/056253 | 7/30/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/020536 | 2/6/2014 | WO | A |
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