JPS63174258A - Halide metal display lamp - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a metal halide discharge lamp,
The present invention relates to such discharge lamps containing sodium and scandium metal halides which have a particularly good lumen output.

Metal halide discharge lamps were introduced commercially in the United States in the early 1960s. Externally, these metal halide discharge lamps resemble mercury vapor discharge lamps and contain an internal arc tube filled with quartz arc support material and surrounded by an external glass envelope. Like mercury vapor discharge lamps, the arc tube filling of metal halide discharge lamps contains a rare gas for starting and a certain amount of mercury. However, the emission spectrum of the lamp is determined primarily by the metal halide filling, usually iodide, in the arc tube.

These metal halides make it possible to obtain higher luminous efficiency and better color rendition of discharge lamp output than mercury vapor discharge lamps. Luminous efficiency, color rendering index, and other discharge lamp output characteristics can be varied by varying the metal halide composition within a particular arc tube fill. It is said that there are more than 50 different metal halides that can be used alone or in combination in metal halide discharge lamps. However, these commercially successful combinations fall into three categories. Indium-thallium-sodium discharge lamps and thorium-thallium-sodium discharge lamps were introduced by Neural Electric and Sylvania in the early 1960s, and by Multivapor and Metalar.
Each was sold under the trademark C. Thorium-thallium-sodium discharge lamps were later replaced by scandium-sodium discharge lamps. Additionally, dysprosium-thallium-indium discharge lamps were introduced by Westinghouse and sold under the trademark BOC.

"Electric Discharge Lamp (Elec
tric Discharge Lagips) J
, John F., Wa.
ymouth), The M.I.T. Press (The
MIT Press), 211 pages (1971)
reference.

Of these, the thallium-indium-sodium combination provides superior color rendering with sodium contributing to the yellow part of the spectrum, thallium contributing to the green part, and indium contributing to the blue part. It became clear that it would.

Such combinations are currently enjoying commercial success in Europe. However, in the United States, sodium scandium discharge lamps are widely used due to their exceptional luminous efficiency (typically 85 to 90 lumens per watt) and long operating life (-10,000 to 100 lumens per watt).
5,000 hours), it has actually begun to be put into practical use worldwide.

Despite the commercial success of metal halide discharge lamps, it is a common objective to further increase the luminous efficiency, color rendering index and operating life of these discharge lamps. For example, in British Patent No. 1,125,063, lithium is added to an indium-thallium-sodium halide discharge lamp to improve color rendering by increasing emission in the red part of the spectrum. In U.S. Pat. No. 3.52L 110, tin, antimony or bismuth was added to increase operating life.
Added to indium-thallium-sodium halide discharge lamps.

Because of its satisfactory luminous efficiency and excellent operating life, and because of its wide commercial acceptance in the United States, further improvements to sodium-scandium metal halide discharge lamps are desirable.

Therefore, it is an object of the present invention to further increase the luminous efficiency of sodium-scandium metal halide discharge lamps.

It is also an object of the present invention to increase the luminous efficiency of the above-mentioned discharge lamp while maintaining or increasing the color rendering index of the above-mentioned discharge lamp.

According to the present invention, a sealed internal arc tube, electrodes positioned spaced apart from each other in the arc tube, conductive wires electrically connected to the electrodes, and a rare gas filled in the arc tube - In a metal halide discharge lamp equipped with a discharge maintenance filling mainly composed of halides of mercury, sodium, and scandium, the filling further contains thallium halide in a molar ratio of sodium halide to thallium halide of about 280. : It is characterized by containing in a ratio of 1 to 75:1. This increases the luminous efficiency of the discharge lamp without substantially adversely affecting the color rendering index of the discharge lamp.

According to a preferred embodiment, the molar ratio of sodium halide to thallium halide is maintained within the range of about 260:1 to 240:1. This improves both the luminous efficiency and color rendering index of the discharge lamp.

According to FIG. 1, a metal halide discharge lamp 10 is similar in structure to a conventional high-pressure mercury vapor discharge lamp, and is arranged near opposite ends of a sealed inner tube or arc tube, respectively, to discharge a vapor discharge. It includes an arc tube 12 having electrodes 14 spaced apart by a predetermined spacing to maintain the arc tube. An inert ionizable starting gas, such as an amount of mercury 16 and a lesser amount of argon, is contained within the arc tube 12. Other noble gases (rare gases) can also be used in place of argon, and gas pressures can also be varied.

The filling amount of mercury 16 is within a predetermined amount range known from the prior art. See, for example, the article listed in U.S. Pat. No. 3,979,624, column 2.53 et seq. Similarly, the interior of the arc tube 12 contains an alkali metal halide I8 of sodium iodide, sodium bromide, or a mixture thereof, and a scandium halide 20 of scandium iodide, scandium bromide, or a mixture thereof. As is known,
The molar ratio of all alkali halides to all scandium halides must be maintained within the range of about 50;1 to 25=1; below this range:
The discharge lamp output tends to begin to take on a bluish color, and beyond this range the discharge lamp output tends to begin to take on a pinkish color. The total amount of alkali metal halides and scandium halides is approximately 0.004 mmol (per Im of spacing between the arc tube electrodes).
(millimol).

To protect the arc tube 12 and to avoid wasting heat, a transparent, sealed outer casing 22 surrounds the arc tube 12 in a spaced manner. Arc tube 12 and outer box 22
Depending on the particular field of application and the operating conditions of the discharge lamp, the spacing can be evacuated or filled with gas. A conductive wire 24 is enclosed within both the outer casing 22 and the inner tube 12 and is used to electrically connect the actuation electrode 14 to an external power source.

A starting electrode 26 is provided within the arc tube 12 and a starting resistor 28 is provided within the arc tube 12.
It is connected to one end of the electrical conductor 24 via. arc tube 12
The insulating sleeve 3 is spaced apart from the outer casing 22.
2 is maintained by a conventional support frame 30 surrounded in a known manner. A ribbon conductor 34 hermetically encapsulates the wire at the end of the arc tube. The conductor is enclosed in the housing 22 by a conventional recessed press-type stem 36 and connected to a standard oversized cap (Mogal base) 38, not shown, for connection to a standard screw-type cap socket. The discharge lamp 10 is designed to operate with 400 watts of power.

The arc tube 12 is made of quartz glass.

Alternatively, the arc tube envelope may be formed from densely sintered polycrystalline or single crystal alumina. In this case, it is impractical to pressure seal the ends of the arc tube. Thus, the alumina arc tube is sealed by using a separate end member. The arc tube 12 has a volume of about 12.3 cd, and the distance between the ends of the electrodes 14 is about 44.5 cd.

According to the invention, there is a small amount of additional thallium halide in the arc tube, such as iodide or bromide or mixtures thereof. It has been discovered that such additives serve to increase the luminous efficiency of the discharge lamp without substantially adversely affecting the color rendering index of the discharge lamp. For this purpose, thallium halide is present in a molar ratio of about 280:1 to about 75:1 with sodium halide.

If it is less than this, the luminous efficiency will not increase as expected due to insufficient thallium, and if it exceeds this, the color rendering index of the discharge lamp will be adversely affected.

In a preferred embodiment of the invention, the molar ratio of sodium halide to thallium halide is between about 260=1 and 240=
Keep it within the range of 1. Within this range, not only the luminous efficiency of the discharge lamp but also the color rendering index is improved.

“Color rendering index J (colorr
The word enderiB 1ndex) is K.L.
Kelty (K, L-Kelty) and D-Heage F (D.

NBS Special Publication 440 by J.B.
Writing Handbook J (IES Light
ingHandbook). As is known, in the evaluation method described above, the output of the discharge lamp is visually compared with successive standard color chips. Each chip is assigned an evaluation number and a weight value. The average weight value of the eight evaluation numbers is employed as a color rendering evaluation number.

The following examples demonstrate the effects on lumen output, color rendering index, and other discharge lamp output characteristics of various levels of scandium iodide added to a sodium-scandium discharge lamp.

4 marked A to D for 400W metal halide discharge lamps
The two lofts comprised a filling of approximately 51.51 g of mercury, 35 torr of argon, 46 mg of sodium iodide, IIIg of scandium iodide, and 5+ wg of mercury iodide. As shown in Table 1 below, Lot A containing 6 discharge lamps was selected as a control, while Lots B and C each having 5 discharge lamps.

Various amounts of thallium iodide were added to D.

The discharge lamp was operated open for 100 hours, then the operating power (
■), luminous effect displayed in output units of lumen/W (LPW), color rendering index (CRT), color temperature (CCT)
), and standard color coordinates (X and Y) measurements. The results are shown in Table II below. Here, the average value (-) for each loft is shown along with the standard deviation (SD) for the loft.

lyuad V(S, D,) LPW(S,
D,) Y - CT at C (S, D,) -
niro r1nuko Lyu p4] A 136.2 (3,4)
85.4 (2,7), 391.394 38!50
(175) 58.6 (4) 8 136.6 (3,5)
94°6 (1,7) , 384.420 4167
(58) 62.0 (2) C131,8 (1,9)
96.2(2), 381.434 432604
0) 58.5 (1) D 128.8 (3,4)
97.3(2), 374.4. Hl 4528 (
112) 55.2 (2) 0.4 m as shown in Table II
Lot B containing g of thallium iodide exhibits an average luminous efficiency of 94.6 lumens/-. This is the control standard Roff I
This is an increase of about 11.chi. from the average value of 85.4 lumens/- obtained in -A. The color rendering index of loft B is 62.0. This value is an increase of approximately 6.chi. over the color rendering index of 58.6 obtained for the control loft A. As is evident from Table U, the luminous efficiency continues to increase with increasing levels of thallium iodide to 97.3 lumens/- for Lot B, which is more than a 14% increase over that for Control Loft A. be.

However, it was found that as the content of thallium iodide increased beyond the 0.4 tag level of Lot B, the color rendering index decreased. However, for Lot D, the CRI ranged from 58.6 to 55 vs. Control Lot A.
．． 2 by about 6χ. Such discharge lamps can be applied for special case uses such as sports lighting. In this case, more green radiation is desirable.

To determine the ability of the discharge lamp of the present invention to maintain high luminous efficiency over a longer operating life, Lot A
and B is the operating power (V), lumens per watt (
LPW) and color temperature (OCT) were measured and evaluated after 2,500 hours and 5,000 hours. The maintenance (χM) of the discharge lamp was calculated by the following formula: As a result, the standard deviation (SD) for the loft and the average value (-) for each lot were obtained as shown in Table III below.

A 2.500 139 (3,1) 72.3(
2,4) 4024 (154) 84.6B 5.0
00 137.7 (2,0) 62.4 (9,8) 3
952 (218) 73.1B 2.500 139
．． 4 (2,1) 79.5 (0,7) 4469 (7
8) 84. OB 5,000 142.0 (2,6
) 71.5 (2,8) 4350 (91) 75.
From the table below, discharge lamps with adducts of thallium iodide (
The maintenance of lot B) is 2.5% compared to the maintenance of the discharge lamp without any additions (lot A).
This is comparable after 00 hours of lighting, and s,
It can be seen that after being lit for ooo hours, it is slightly better than this. In fact, at time s,ooo
The -B discharge lamp exhibits an LPW that is 14.6χ higher than that of the L-A discharge lamp, and becomes 11χ higher at 100 hours.

The color change between the lot A and lot B discharge lamps was significant.

[Brief explanation of the drawing]

The drawing is a partially sectional front view of a metal halide discharge lamp according to the present invention. 12... Arc tube 14... Electrode 22... Outer casing 24... Conductor wire 26... Starting electrode

Claims (1)

[Claims] 1. A sealed internal arc tube, electrodes positioned apart from each other in the arc tube, a conductive wire electrically connected to the electrodes, and a conductive wire filled in the arc tube. Noble gas, mercury,
In a metal halide discharge lamp comprising a discharge maintenance filling mainly composed of halides of sodium and scandium, the filling further contains thallium halide in a molar ratio of sodium halide to thallium halide of about 2.
80:1 to 75:1, the molar ratio of sodium halide to thallium halide is in the range of about 260:1 to 240:1. The metal halide discharge lamp 3 according to claim 1, wherein the molar ratio of sodium halide to scandium halide is within the range of about 50:1 to 25:1. metal halide discharge lamp