US3398312A

US3398312A - High pressure vapor discharge lamp having a fill including sodium iodide and a free metal

Info

Publication number: US3398312A
Application number: US516200A
Authority: US
Inventors: Charles R Edris; Hugh D Fraser; Melvin C Unglert
Original assignee: Westinghouse Electric Corp
Current assignee: Philips North America LLC
Priority date: 1965-11-24
Filing date: 1965-11-24
Publication date: 1968-08-20
Anticipated expiration: 1985-08-20
Also published as: JPS4938152B1

Description

Aug. 20, 1968 c. R. EDRIS ETAL 3,398,312

HIGH PRESSURE VAPOR DISCHARGE LAMP HAVING A FILL INCLUDING SODIUM IODIDE AND A FREE METAL Filed Nov. 24, 1965 WITNESSES INVENTORS Charles R. Edris, Hugh D. Fraser and Melvin C.Ungler1 a pzzw,

ATTORNEY United States Patent 3,398,312 HIGH PRESSURE VAPOR DISCHARGE LAMP HAV- ING A FILL INCLUDING SODIUM IODIDE AND A FREE METAL Charles R. Edris, Nutley, Hugh D. Fraser, Caldwell, and

Melvin C. Unglert, Wyckoif, N.J., assignors to Westinghouse Electric Corporation, Pittsburgh, Pa., 2 corporation of Pennsylvania Continuation-impart of application Ser. No. 317,508, Oct. 21, 1963. This application Nov. 24, 1965, Ser. No. 516,200

7 Claims. (Cl. 313-225) ABSTRACT OF THE DISCLOSURE Mercury-metal iodide discharge lamp includes sodium iodide as a discharge-sustaining constituent and additional free metal, such as thallium, is also included as a part of the dosing charge. During operation of the device, -free iodine is released through reaction of sodium with the arc tube. This released free iodine reacts with the aditional free metal to prevent changes in lamp starting and operating characteristics, as well as to prevent color shifts.

This application is a continuation-in-part of application Serial No. 317,508, abandoned filed October 21, 1963, and owned by the present assignee.

This invention relates to discharge devices and, more particularly, to a high-pressure, vapor-discharge lamp of the so-called additive type.

It is known to modify high-pressure, mercury-vapor discharge lamps by including additive materials, and particularly selected metallic iodides, in the arc tube. In the operation of such devices, the mercury, which is fully .vaporized, normally establishes the proper loading or voltage drop across the lamp and the additive iodides improve the color and luminous output of the discharge. Such socalled additive lamps are generally disclosed in Illuminating Engineering Society, Paper 29, entitled Higher Efiiciency Light Source Through the Use of Additives to Mercury Discharge, September 1962.

Particularly where sodium iodide is used as one of the additive constituents, the sodium has some tendency to react with the arc tube envelope and possibly with other are tube parts during operation. This release free iodine, which in turn increases the voltage required to initiate the discharge, thus making the lamp difficult to start. In addition, the lamp operating voltage is increased. From a commercial standpoint, it is usually desirable that the discharge has a substantially constant color throughout lamp life.

It is the general object of this invention to provide a so-called additive-type, high-pressure discharge lamp which operates with improved performance.

It is another object to provide a high-presure discharge lamp which incorporates sodium iodide as an additive material, and which lamp has a substantially constant color throughout its life.

It is a further object to provide a sodium iodide-mercury high-pressure discharge lamp which can be readily started throughout its life and which has a substantially constant operating voltage.

The aforesaid objects of the invention, and other objects which will become apparent as the description proceeds, are achieved by using a discharge-sustaining filling comprising a predetermined amount of sodium iodide in addition to a predetermined amount of mercury which will provide the device with the proper voltage drop, and a small amount of inert ionizable starting gas. There is also included a small predetermined amount of selected metal. When such a device is operated, the small amount of 3,398,312 Patented Aug. 20, 1968 free iodine which is released when the sodium reacts with the arc tube and other parts of the device is reacted with the selected metal to form an iodide. Since the free iodine is combined with the added selected metal, the starting and operating characteristics of the device are not impaired by reaction of sodium with the arc tube.

In the preferred form of the invention, both sodium iodide and thallium iodide are utilized. When the sodium reacts with the arc tube to release free iodine, the additive selected metal, such as thallium or indium metal, reacts With this released iodine.

For a better understanding of the invention, reference should be had to the sole figure of the drawing wherein therein is illustrated a lamp constructed in accordance with the plesent invention and shown in operating position, with the energizing power source electrically connected to the lamp.

While the teachings of the present invention are applicable to lamps or discharge devices of varying size and designed wattage input, high-pressure vapor-discharge lamps having a designed power input of 400 watts are used extensively, and hence such a lamp has been illustrated and will be so described.

With specific reference to the form of the invention illusstrated in the drawing, the lamp 10 is generally similar in construction to the usual high-pressure, mercury-vapor (HPMV) lamp, such as described in US. Patent No. 2,748,303, dated May 29, 1956, to Thorington. The lamp 10 generally comprises a radiation-transmitting sealed inner envelope or are tube 12 having electrodes 14 disposed proximate to either end thereof and operable to sustain a vapor discharge therebetween. A charge of mercury 16 and a small charge of inert ionizable starting gas, such as argon, are contained within the inner envelope 12. The charge of mercury is present in predetermined amount so that when the mercury is fully vaporized during operation of the lamp, the proper voltage drop across the lamp and power input to the lamp will be realized. Thallium iodide 18 is contained within the inner envelope in an amount of from 0.035 to 0.9 mg./cc. of total volume enclosed by the arc tube .12. Also included in the arc tube 12 is sodium iodide 20 in an amount of at least 0.17 mg./cc. of volume enclosed by the arc tube, and thallium metal 22 in an amount of at least about 0.031 mg./cc. of volume enclosed by the arc tube 12.

A radiation-transmitting, sealed, outer envelope 24 is spaced from and surrounds the arc tube 12, and electrical lead-in conductors 26 are sealed through both the arc tube 12 and the outer envelope 24 and serve to electrically connect the operating electrodes 14 to a conventional power source 28.

A starting electrode 30 is also included within the arc tube 12 and connects through a starting resistor 32 to one of the electrical lead-in conductors 26. The are tube 12 is maintained in spaced relationship from the outer envelope 24 by means of a conventional supporting frame 34. Ribbon conductors 36 serve to facilitate hermetic-ally sealing the lead-in conductors 26 through the ends of the arc tube 12. The lead-in conductors are sealed through the outer envelope 24 by means of a conventional re-entrant stern press 38 and connect to a standard mogul base 40 to facilitate electrical connection to the power source 28. As indicated hereinbefore, the power source 28 is generally conventional, and is designed to deliver a predetermined power input or loading to the lamp 10. For the specific lamp as described, the power input is 400 watts.

In accordance "with the present invention, the thermal conductivity from the arc tube 12 and the predetermined power input at which the arc tube is designed to 'be operated bear such relationship to one another that the minimum temperature on the arc tube When the lamp is operated is at least 5 80 C. Even when substantially horizontally positioned, one end of the arc tube 12 will normally be slightly lower than the other end of the arc tube, and this lowest portion 42 of the arc tube 12 will normally be the coolest portion at which the nonvaporized iodides will collect during operation.

As a specific example, the distance between the operating electrodes 14 is approximately 57 mm. and the arc tube 12 encloses a predetermined volume of approximately 28.8 cc. The mercury charge 16 is included in amount of 117 mg. and this will provide the lamp with an operating potential of approximately 135 volts. It should be clearly understood that the amount of mercury which is utilized is predetermined in accordance with the desired operating voltage which is developed across the lamp lead-in conductors 26. The determination of the proper amount of mercury to achieve a predetermined voltage drop for any specific lamp is well known, and is generally described in US. Patent No. 2,892,665, dated June 30, 1959. If the present lamp were desired to be operated under either higher or lower voltage and power conditions, the proper charge of mercury to provide such a desired operating voltage could be readily determined. As a specific example, sodium iodide is used in amount of about 0.7 to 1 mg./cc. of arc tube volume, thallium iodide is used in amount of about 0.17 mg./cc. of arc tube volume, and thallium metal is used in amount of about 0.7 mg./cc. of volume enclosed by the arc tube 12. The inert, ionizable starting gas fill in the arc tube 12 can be modified considerably with respect to the gas used and the gas pressure. As a specific example, the arc tube 12 is charged with argon starting gas at a pressure of approximately 20 mm. Hg.

When the lamp is initially started, a discharge will be established between the starting electrode 30 and the adjacent main operating electrode 14. Thereafter a discharge will be established between the two operating electrodes 14, which will heat all of the mercury charge 16 to a fully vaporized condition. As the mercury becomes fully vaporized, the operating temperature of the arc tube 12 will increase and a portion of the thallium iodide and sodium iodide will vaporize, along with a very small portion of the thallium metal. When a sufiicient amount of these iodides are vaporized, the discharge essentially assumes the characteristics of a sodium iodide discharge, as modified by the thallium iodide, and the yellow and green mercury lines are suppressed and furnish only about fifteen percent of the total light output. Thus the primary function of the mercury is to provide the lamp with adequate loading and adequate voltage drop, which in turn enables a sufiicient vapor ressure of sodium and thallium iodides to be achieved without resorting to excessive operating currents and very low operating voltages. The sodium iodide is present in amount of at least 0.17 mg/cc. of arc tube volume and preferably from 0.6 to 4.5 mg./cc. of arc tube volume in order to provide adequate sodium iodide vapor pressure during operation. The thallium iodide is present in amount of from 0.035 to 0.9 mg./cc. of volume and preferably from 0.1 to 0.3 mg./cc. of volume enclosed by the arc tube in order that the discharge always has a sufiicient thallium iodide component so that additional thallium iodide which is formed during operation of the lamp will not measurably afiect the overall color emitted by the lamp. The thallium metal preferably is present in amount of from 0.4 to 1.7 mg./ cc. of volume enclosed by the arc tube 12 in order to ensure that throughout lamp life there is suificient thallium metal present to react with the free iodide which is released. Thus the lamp starting voltage remains constant and the color output of the composite discharge is substantially constant throughout lamp life.

In actual operation, the specific lamp as described hereinbefore will have an initial luminous efficiency of approximately to lumens per watt. The starting voltage for this lamp is approximately 250 volts and will remain constant throughout rated life. The color of the discharge is a combination of sodium iodide, thallium iodide and mercury. The sodium iodide discharge has a slightly pinkish hue, the thallium iodide discharge has'a greenish hue and the mercury discharge is essentially a yellow line and a green line. The color rendition of objects illuminated by such a discharge is excellent.

Small amounts of other additive materials may be used to supplement the primary discharge-supporting sodium iodide and thallium iodide additives. For example, a small amount of indium iodide, zinc iodide or lithium iodide when added to the arc tube will modify the sodium iodide-thallium iodide discharge slightly, in order to produce a modified color output.

If color shifts in the lamp output can be tolerated, or are desired, small amounts of selected metal can be added to a sodium iodide-mercury lamp or to a sodium-iodide thallium-iodide mercury lamp, for example, in order to provide a reservoir of metal which will react with any free iodine that may be released during operation of the lamp as a result of reaction of the sodium with the arc tube. In accordance with the present invention, the discharge-sustaining filling is initially placed into the arc tube as a so-called dosing charge. This dosing charge includes as essential constituents a predetermined pressure of inert ionizable starting gas, as specified hereinbefore, along with a predetermined amount of mercury, sodium iodide, and a predetermined amount of selected metal which will combine with free iodine to form metallic iodide, and thus prevent hard starting lamps and excessive operating voltages caused by the presence of free iodine.

As specified hereinbefore, the mercury constituent of the dosing charge is present in predetermined amount which when fully vaporized during normal operation of the lamp will provide a predetermined pressure of mercury vapor in the arc tube. The sodium iodide constituent of the dosing charge is present in amount of at least 0.17 mg./cc. of arc tube volume, and preferably in amount of from 0.6 to 4.5 mg./ cc. of arc tube volume.

The selected metal constituent of the dosing charge is present in predetermined amount which is at least suflicient to react with additional iodine in amount of 4.5 x10 gram-atom of iodine per cubic centimeter of arc tube volume. As an example, assume that indium metal is added in amount of 0.5 mg. and isused to replace the thallium metal in the specific arc tube as described hereinbefore. This amount of indium will react with iodine in amount of about 4.5X10 gram-atom per cubic centimeterof arc tube volume. Preferably an additional amount of indium or other metal is used over the minimum amount as specified, and as a specific example, the arc tube as described hereinbefore is dosed with mercury in amount of 117 mg., sodium iodide in amount of 20 to 30 mg. (about 0.7 to 1 mg./cc. of volume), thallium iodide in amount of 5 mg. (about 0.17 mg./cc. of volume), and indium metal in amount of 2 mg. (about 0.07 mg./ cc. of volume). When the arc tube is initially energized, the indium metal reacts with iodine in the arc tube to supplement the discharge with the characteristics of the indium iodide spectrum, although there will remain a reservoir of metal to react with any released iodine.

Many other metals can be added to the arc tube as a part of the dosing charge in order to provide a reservoir of metal which reacts with any released iodine. As a specific example, the arc tube as described hereinbefore can be dosed with 117 mg. of mercury, 25 mg. of sodium iodide, and 17x10 mole of any one of zirconium, lead, gallium, tin, cadmium, zinc, scandium, calcium, germanium, yttrium, or cerium, or any mixtures thereof. The additive metal should be used at least in such amount as required to react with 4.5 X 10- gram-atom of iodine per cubic centimeter of arc tube volume. Preferably the additive metal is not used in excess of such amount as required to react with 25 10- gram-atom of iodine per cubic centimeter of arc tube volume. Of course, the amount of additive metal to be added within this range will alter the spectral output of the lamp, and the exact amount of such metal as used will be dependent upon the desired color. It should be understood, however, that the improved starting and operating characteristics of the lamp will be achieved by the addition of any of the specified metals when used in the minimum amount as specified. In addition, the foregoing list of additive metals is not complete, but is only illustrative.

As a possible alternative embodiment, the halogen component of the discharge-sustaining filling in the arc tube may be dosed therein in the form of mercury iodide. Upon initial energization of the lamp, the other active metallic components of the dosing charge will react with the mercury halide to free the mercury. In any case, in the dosing charge as placed into the arc tube, the amount of active combined and uncombined metal in the dosing charge, other than mercury, is predetermined to: (1) combine stoichiometrically with the total amount of combined iodine in the dosing charge plus (2) provide at least sufi'icient metal to combine with additional iodine in amount of 4.5 gram-atom per cubic centimeter of arc tube volume. This represents the minimum amount of metallic reservoir which should be used in order to obtain good starting and operating characteristics for the lamp.

It will be recognized that the objects of the invention have been achieved by providing an improved highpressure, gas-discharge lamp of the additive type which operates with improved performance in that the starting voltage and operating voltage are substantially constant throughout lamp life. In the preferred form of the invention, the color of the lamp does not change during life.

While preferred embodiments of the present invention have been illustrated and described in detail, it is to be particularly understood that the invention is not limited thereto or thereby.

We claim as our invention:

1. A discharge lamp adapted to be normally operated with a predetermined power input, said lamp comprising:

(a) a light-transmitting elongated arc tube which encloses a predetermined volume;

(b) arc-supporting electrodes disposed within said are tube proximate the ends thereof;

(c) lead-in conductors connecting to said electrodes and sealed through said are tube;

(d) a discharge-sustaining filling within said are tube, said discharge-sustaining filling initially placed as a closing charge into said are tube, said dosing charge including as essential constituents a predetermined pressure of inert ionizable starting gas, mercury, sodium iodide, and a predetermined amount of selected metal which will combine with free iodine as may be released during operation of said lamp to form metallic iodide,

(1) said mercury constituent of said dosing charge present in predetermined amount which when fully vaporized during normal operation of said lamp will provide a predetermined pressure of mercury vapor in said arc tube,

(2) said sodium iodide constituent of said dosing charge present in amount of at least 0.17 mg./ cc. of said are tube volume,

(3) said selected metal constituent of said dosing charge present at least in amount sufi'icient to react with free iodine, as may be released during operation of said lamp, in amount of 4.5 10' gram-atom of iodine per cc. of said are tube volume, and

(4) the amount of combined and uncombined metal in said dosing charge, other than mercury, being predetermined to:

(a) combine stoichiometrically with the total amount of iodine in said dosing charge plus (b) provide at least sutficient metal to combine with free iodine, as may be released during operation of said lamp, in amount of 4.5 10 gram-atom of iodine per cc. of said are tube volume; and

(e) the thermal conductivity from said are tube and the predetermined power input at which said lamp is adapted to be operated bearing such relationship to one another that the minimum temperature on said are tube when said lamp is operating is at least 580 C.

2. The discharge lamp as specified in claim 1, wherein said dosing charge includes sodium iodide in amount of from 0.6 to 4.5 mg./cc. of said are tube volume.

3. The discharge lamp as specified in claim 2, wherein said dosing charge also includes thallium iodide in amount of from 0.035 to 0.9 mg./cc. of said are tube volume.

4. The discharge lamp as specified in claim 1, wherein said dosing charge includes sodium iodide in amount of from about 0.7 to 1 mg./cc. of said are tube volume, thallium iodide in amount of about 0.17 mg./cc. of said are tube volume, and indium metal in amount of about 0.07 rng./cc. of said arc tube volume.

5. The discharge lamp as specified in claim 1, wherein said dosing charge includes sodium iodide in amount of from about 0.6 to 4.5 mg./cc. of said are tube volume, thallium iodide in amount of from about 0.1 to 0.3 rug/cc. of said are tube volume, and thallium metal in amount of from about 0.4 to 1.7 mg./ cc. of said arc tube volume.

6. The discharge lamp as specified in claim 1, wherein said selected metal constituent of said dosing charge is present in amount snfiicient to react with additional iodine in amount of from 4.5 10"' to 25 10- gram-atoms/ cc. of said are tube volume.

7. The discharge lamp as specified in claim 1, wherein said selected metal of said dosing charge is at least one metal of the group consisting of zirconium, lead, gallium, tin, cadmium, indium, thallium, zinc, scandium, calcium, and germanium.

References Cited UNITED STATES PATENTS 2,971,110 2/1961 Schmidt 313-227 3,234,421 2/1966 Reiling 313----225 3,334,261 8/1967 Butler et al. 313-227 X FOREIGN PATENTS 631,755 11/1963 Belgium. 1,177,248 9/ 1964 Germany.

I AMES W. LAWRENCE, Primary Examiner. S. A. SCHNEEBERGER, Assistant Examiner.