The present invention relates to ceramic metal halide lamps and discharge tubes. More particularly, the present invention relates to a high pressure, high mercury density ceramic metal halide discharge lamp that does not suffer from light output intensity lowering or large color shifts as the lamp ages.
Discharge lamps produce light by ionizing a fill material, such as a mixture of metal halide and mercury in an inert gas, such as argon, with an arc passing between two electrodes. The electrodes and the fill material are sealed within a translucent or transparent discharge vessel or discharge tube, which maintains the pressure of the energized fill material and allows the emitted light to pass through. The fill material, also known as a “dose,” emits a desired spectral energy distribution in response to being excited by the electric arc. For example, halides provide spectral energy distributions that offer a broad choice of light properties, including color temperatures, color rendering, and luminous efficiency.
Discharge tube chambers composed of fused silica “quartz” are readily formed. However, the lifetime of such lamps is often limited by the loss of the metal portion of the metal halide fill (typically sodium) during lamp operation. Sodium ions diffuse through, or react with, the fused silica discharge tube, resulting in a corresponding build-up of free halogen in the discharge tube. Quartz discharge tubes are relatively porous to sodium ions. During lamp operation, sodium passes from the hot plasma and through the discharge tube wall to the cooler region between the discharge tube and the outer jacket or envelope. The lost sodium is thus unavailable to the discharge and can no longer contribute its characteristic emission. The light output consequently diminishes and the color shifts from white toward blue. The arc becomes constricted and, particularly in a horizontally operated lamp, may bow against the discharge tube wall and soften it. Also, loss of sodium causes the operating voltage of the lamp to increase and it may rise to the point where the arc can no longer be sustained, ending the life of the lamp.
Ceramic discharge lamp chambers were developed to operate at higher temperatures than quartz, i.e., above 950° C., for improved color temperature, color rendering, and luminous efficacies, while significantly reducing reaction with the fill material. U.S. Pat. Nos. 5,424,609; 5,698,984; and 5,751,111 provide examples of such discharge tubes. While quartz discharge tubes are limited to operating temperatures of around 950° C. to 1000° C., due to reaction of the halide fill with the quartz, ceramic alumina discharge tubes are able capable of withstanding operating temperatures of 1000° C. to 1250° C. or higher. The higher operating temperatures provide better color rendering and high lamp efficiencies. Ceramic discharge tubes are less porous to sodium ions than quartz tubes and thus retain the metal within the lamp. Various techniques are available for fabricating the discharge tubes, including casting, forging, machining, and various powder processing methods, such as powder injection molding (PIM). In powder processing, a ceramic powder, such as alumina, is supported by a carrier fluid, such as a water-based solution, mixture of organic liquids, or molten polymers. The mixture can be made to emulate a liquid, a plastic, or a rigid solid, by controlling the type and amount of carrier and the ambient conditions (e.g., temperature).
The use of ceramic in high wattage metal halide lamps has improved the useful life and performance of such lamps. Nevertheless, ceramic metal halide lamps still suffer from progressively poorer light output (lumen maintenance) and color shift as the lamp ages and wattage is decreased. This makes it very difficult to manufacture a practical low wattage metal halide lamp having suitable performance.
In addition, typical low wattage ceramic metal halide lamps offer only marginal performance. For example, most 20 watt lamps suffer from such poor light output that their use in most commercial and personal applications are severely limited.
Thus, a need exists for a low wattage ceramic metal halide lamp that provides acceptable performance and lumen maintenance and exhibits minimal through-life color shift.
In an exemplary embodiment of the present invention, a metal halide lamp is provided. The metal halide lamp includes a discharge vessel, an outer lamp envelope enclosing the discharge vessel, a pair of electrodes sealed in opposing ends of the discharge vessel, and an ionizable fill contained in said discharge vessel. The ionizable fill comprises mercury in a concentration of from 0.11 to 0.20 mg/mm3.
In another exemplary embodiment of the present invention, a discharge vessel is provided. The discharge vessel includes a tubular body of a translucent ceramic material, first and second end walls closing opposite ends of the tubular body to define a discharge space, first and second projecting tubes attached to the first and second end walls, respectively, and extending away from the tubular body, an ionizable fill contained in the tubular body for creating a discharge, the ionizable fill comprising mercury in a concentration of from about 0.11 mg/mm3 to 0.20 mg/mm3, first and second electrodes supported in the chamber, the first electrode extending through and sealed in said first projection tube, said second main electrode extending through and sealed in said second projection tube.
One advantage of at least one embodiment of the present invention is that a ceramic metal vapor lamp is provided which maintains superior lumen maintenance compared to conventional ceramic metal halide lamps.
Another advantage of at least one embodiment of the present invention is the provision of a high efficiency, low wattage ceramic metal halide lamp suitable for use in retail, office and architectural lighting applications.
Still further advantages of the present invention will become apparent to those of ordinary skill in the art upon reading and understanding the following detailed description of the preferred embodiments.
With reference to
The discharge space 14 contains a fill of an ionizable gas mixture such as metal halide and inert gas mixture. Suitable metal halide fills include at least one metal halide, such as sodium iodide, thalium iodide, or dysprosium iodide, in addition to mercury and a rare gas, such as Argon or Xenon. Other suitable fills for initiating and sustaining an arc discharge known in the art are also contemplated. With reference to
The two electrodes 20, 22, which may be formed from tungsten, extend into the discharge space 14 and have their tips 24, 26 separated by an arc gap 30. With further reference to
It will be appreciated that other known electrode materials may alternatively be used. The electrodes 20, 22 are spaced by a gap 30 of about 2-3millimeters. A discharge forms between the tips of the electrodes 24, 26 when a voltage is applied across the electrodes. The lamp outer jacket 40 may be either a vacuum or gas filled.
The design of the present discharge tube provides a much higher mercury density than found in conventional metal halide lamps. As can be seen in
A further characteristic of the present design is that the discharge tube operates at a much higher internal pressure than conventional discharge tubes. The discharge tube in one embodiment of the present invention operates at a pressure of from about 80 to about 170 atmospheres (assuming an average discharge tube temperature of 2000 K), preferably about 100 atmospheres. This is far in excess of the operating pressure of typical metal halide lamps, which range from about 9 atmospheres for a 150-watt lamp to about 23 atmospheres for a 35-watt lamp.
Another characteristic of a discharge tube according to one embodiment of the present invention is that the lamp voltage is increased from a typical value of 90 volts to about 120 volts. In order to accommodate the higher mercury density at this voltage, the arc gap may be made shorter than is conventional in typical discharge tubes. This improves the light gathering capability of the lamp and allows smaller, more efficient reflectors to be used in the fixtures.
With reference to
In one embodiment of the present invention, a typical discharge tube has the following dimensions and characteristics.
Inner bulb length: 4.8-5.3 mm
Inner bulb diameter: 3.8-4.2 mm
Arc gap: 2.8-3.0 mm
Mercury weight: 4.2-8.2 mg
Mercury density: 0.10-0.20 mg/mm3
Operating pressure: 80-170 atmospheres
The higher mercury density, higher pressure discharge tubes of the present invention offer significant performance benefits than current ceramic metal halide lamps. They offer improved lumen maintenance and reduced through-life color shift over comparable lower mercury density designs of the same lamp wattage. The present lamps find use as low energy alternatives to low voltage halogen display lamps in retail, office, stage/studio, and architectural lighting applications.
The ceramic discharge tube may be formed from a single component or from multiple components. In a first embodiment, the discharge tube 10 is assembled from separate components. In the discharge tube of
With further reference to
The discharge tube components are fabricated, for example, by die pressing, injection molding, or extruding a mixture of a ceramic powder and a binder system into a solid body. For die pressing, a mixture of about 95-98% of a ceramic powder and about 2-5% of a binder system is pressed into a solid body. For injection molding, larger quantities of binder are used, typically 40-55% by volume of binder and 60-45% by volume ceramic material.
The ceramic powder may be any material conventionally used in the manufacture of ceramic metal halide discharge tubes. They are preferably formed from a polycrystalline aluminum oxide ceramic, although other polycrystalline ceramic materials capable of withstanding high wall temperatures up to 1700-1900° C. and which are resistant to attack by the, fill materials are also contemplated. The ceramic powder may comprise alumina having a purity of at least 99.98% and a surface area of about 2-10 m2/g. The alumina powder may be doped with magnesia to inhibit grain growth, for example, in an amount equal to 0.03% to 0.2%, preferably, 0.05%, by weight of the alumina. Other ceramic materials which may be used include non-reactive refractory oxides and oxynitrides, such as yttrium oxide, lutecium oxide, and hafnium oxide, and their solid solutions and compounds with alumina, such as yttrium-aluminum-garnet and aluminum oxynitride. Binders which may be used for die pressing, either individually or in combination, include organic polymers, such as polyols, polyvinyl alcohols, vinyl acetates, acrylates, cellulosics, and polyesters. For injection molding, the binder may comprise a wax mixture or a polymer mixture.
For binders which are solid at room temperature, a thermoplastic molding process is preferably used. To carry out thermoplastic molding, sufficient heat and pressure is applied to the ceramic composition to force it to flow to the desired degree depending on the particular thermoplastic molding process employed. The ceramic powder/binder composition is heated to a temperature at which the binder is soft or molten. For most commercial thermoplastic forming techniques, the ceramic composition is heated to make the binder molten at from about 60° C. to about 200° C., shaped under a pressure ranging from about 0.35 kg/cm2 to about 2,100 kg/cm2, depending upon the particular thermoplastic forming technique, and then allowed to cool and harden. For example, in the case of injection molding, the molten ceramic composition is forced into a die to produce the molded product. Specifically, for injection molding, the molten ceramic mixture, preferably at a temperature from about 65° C. to about 90° C. and under a pressure ranging from about 70 kg/cm2 to about 2,100 kg/cm2, is forced into a die where it is allowed to harden and then removed from the die. The die may be cooled to facilitate hardening. A number of thermoplastic molding techniques can be used to produce the present molded body. Representative of such techniques are pressure injection molding, gas-assisted injection molding, extrusion molding, blow molding, compression molding, transfer molding, drawing and rolling.
Other binders, such as aqueous binders, do not need to be heated to form a slurry suitable for molding. For example, in one single piece molding technique, a mold formed from Plaster of Paris is formed in two halves. The mold halves are formed such that when they are mated together, the tubular body portions and projecting tubes are aligned. A slurry formed from a mixture of a ceramic powder (e.g., alumina/magnesia, as described above) and a liquid, such as water, is poured into the mold. The mold is rotated to distribute the slurry over internal surfaces of the mold cavity. Since the Plaster of Paris is absorbent, the water is quickly drawn out of the slurry, leaving a coating of ceramic powder on the internal walls. When dry, the mold halves can be removed leaving the discharge tube ready for further drying, sintering, firing, and other processing.
Subsequent to die pressing, injection molding, single piece molding, or other forming technique, the binder is removed from the “green” part. For example, for die pressed parts, the binder is removed by solvent leaching with hexane, and/or by thermal pyrolysis to form a bisque-fired part. The thermal pyrolysis may be conducted, for example, by heating the green part in air from room temperature to a maximum temperature of about 900-1100° C. over 4-8 hours, preferably, to a temperature of about 200-400° C., and then holding the maximum temperature for 1-5 hours, and then cooling the part. After the thermal pyrolysis, the porosity of the bisque-fired part is about 40-50%. Pyrolysis generally oxidizes and burns out the volatile components.
For injection-molded parts, the binder is removed from the molded part, typically by thermal treatment. The thermal treatment may be conducted by heating the molded part in air or a controlled environment, e.g., vacuum, nitrogen, or rare gas, to a maximum temperature. For example, the temperature may be slowly increased by about 2-3° C. per hour from room temperature to a temperature of about 160° C. Next, the-temperature is increased by about 100° C. per hour to a maximum temperature of about 900-1100° C. Finally, the temperature is held at 900-1100° C. for about 1-5 hours. The part is subsequently cooled. After the thermal treatment step, the porosity is about 40-50%.
The bisque-fired part is then machined, where needed. For example, a small bore or bores may be drilled along the axis of a solid cylinder to provide the bore(s) of the leg portion. The outer portion of the solid cylinder may be machined away, for example with a lathe, to form the outer surface of the leg portion. The machined parts are typically assembled prior to sintering to allow the sintering step to bond the parts together: The densities of the bisque fired parts used to form the barrel and the end plugs is preferably selected to achieve different degrees of shrinkage during the sintering step. The different densities may be achieved by using ceramic powders of different surface areas. Finer powders produce lower densities than coarser ones. The barrel is preferably of lower density than the end plug so that it shrinks more.
For discharge tubes formed by a single piece molding technique, as described above, there are not the same density concerns discussed above, since the green part is a single component, rather than separate components which are joined in the sintering stage. Further, if the size and shape of the mold is carefully selected, machining of the bisque-fired part may not be necessary, since the mold can be used to define the outer surface, including filets and the internal bores. It will be appreciated, however, that this method yields a barrel of generally uniform wall thickness. The thickened portions 50, 52 shown in
The sintering step may be carried out by heating the bisque-fired parts or discharge tube in hydrogen having a dew point of about 10-15° C. or in an inert atmosphere. Argon gas provides a suitable inert atmosphere, although other inert gases are also contemplated. Typically, the temperature is increased from room temperature to about 1300° C. over a two hour period. Next, the temperature is held at about 1300° C. for about two hours. The temperature is then increased by about 100° C. per hour up to a maximum temperature of about 1850-1900° C., and held at that temperature for about three to five hours. Finally, the temperature is decreased to room temperature over about two hours. The inclusion of magnesia in the ceramic powder typically inhibits the grain size from growing larger than 75 microns. The resulting ceramic material comprises a densely sintered, polycrystalline alumina.
Pressures above atmospheric may also be applied during the sintering step. The bisque-fired ceramic is converted, during sintering, from an opaque material to a translucent polycrystalline aluminum oxide. The sintering step also strengthens the joints between the components of the discharge tube. Other sintering methods are also contemplated.
The sinterable ceramic powder preferably has an average particle size of from 0.01-1000 μm, more preferably, below about 50 μm. For discharge tube applications, the average size of the ceramic powder preferably ranges up to about 10 μm and depends largely on the particular densification technique employed, i.e., larger particle sizes can be used in reaction bonding whereas smaller particle sizes would be used in sintering a compact thereof. Preferably, however, the ceramic powder has an average particle size which is submicron and most preferably, it has an average particle size ranging from about 0.05 microns up to about 1 micron.
The invention has been described with reference to the preferred embodiment. Obviously, modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the invention be construed as including all such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.
Number | Name | Date | Kind |
---|---|---|---|
4348615 | Garrison et al. | Sep 1982 | A |
5828185 | Fellows et al. | Oct 1998 | A |
5923127 | Keijser et al. | Jul 1999 | A |
5973453 | Van Vliet et al. | Oct 1999 | A |
6111359 | Work et al. | Aug 2000 | A |
6137229 | Nishiura et al. | Oct 2000 | A |
6137230 | Born et al. | Oct 2000 | A |
6163115 | Ishizuka | Dec 2000 | A |
6172462 | Gibson et al. | Jan 2001 | B1 |
6215254 | Honda et al. | Apr 2001 | B1 |
6222320 | Stockwald | Apr 2001 | B1 |
6285130 | Nakagawa et al. | Sep 2001 | B1 |
6288491 | Ramaiah et al. | Sep 2001 | B1 |
6294870 | Kawashima et al. | Sep 2001 | B1 |
6294871 | Scott et al. | Sep 2001 | B1 |
6342764 | Nishiura et al. | Jan 2002 | B1 |
6356016 | Suijker et al. | Mar 2002 | B1 |
6368175 | Horiuchi et al. | Apr 2002 | B1 |
6369522 | Collins | Apr 2002 | B1 |
6528946 | Ishigami et al. | Mar 2003 | B2 |
6614187 | Kanzaki et al. | Sep 2003 | B1 |
6762559 | Ishikawa et al. | Jul 2004 | B1 |
6798139 | Ramaiah et al. | Sep 2004 | B2 |
6919686 | Okamoto et al. | Jul 2005 | B2 |
7122960 | Tukamoto et al. | Oct 2006 | B2 |
20030102808 | Dakin et al. | Jun 2003 | A1 |
20030173902 | Venkataramani et al. | Sep 2003 | A1 |
20030214234 | Fukushima | Nov 2003 | A1 |
20040095069 | Yamashita et al. | May 2004 | A1 |
20050127841 | Maseki et al. | Jun 2005 | A1 |
20060007410 | Masuoka et al. | Jan 2006 | A1 |
20060022596 | Watanabe et al. | Feb 2006 | A1 |
20060164017 | Rintamaki et al. | Jul 2006 | A1 |
Number | Date | Country |
---|---|---|
0 215 524 | Mar 1987 | EP |
0 286 247 | Oct 1988 | EP |
0 869 540 | Oct 1998 | EP |
0 954 011 | Mar 1999 | EP |
1 225 614 | Jul 2002 | EP |
1 289 001 | Mar 2003 | EP |
WO 2004081963 | Sep 2004 | WO |
WO 2006046175 | May 2006 | WO |
WO 2006078632 | Jul 2006 | WO |
Number | Date | Country | |
---|---|---|---|
20070120493 A1 | May 2007 | US |