TECHNICAL FIELD'
[0001] This invention relates to incandescent lamps and more particularly to the filaments
thereof. Still more particularly, it relates to a method for increasing the life of
such filaments when such filaments are constructed from tungsten.
BACkGROUND OF THE INVENTION
[0002] The use of tungsten filaments in incandescent lamps is well established. Also well
established is the fact that tungsten filaments do not heat to a uniform temperature
upon passage of an electric current therethrough. Rather, localized hot spots are
generally observed. Such hot spots are the filament life-determining factor in a well-made
lamp because of their higher rate of tungsten evaporation. A runaway condition thereby
exists, with evaporation-promoted thinning of the wire and consequent increased ohmic
heating and ever higher localized temperatures.
[0003] Hot spots on a filament may arise because of nonuniform wire cross sectional area,
nonuniform cross sectional shape, variations in wire surface smoothness, nonuniformly
spaced turns or segments of turns in a coiled or coiled coil geometry, and other reasons.
While good lamp manufacturing practice strives to reduce-all such contributing factors,
the presence of hot spots is nevertheless ubiquitous.
[0004] It is well known to those skilled in the art that a halogen cycle based on fluorine
or its compounds differs from those based on bromine and the other halogens in that
with fluorine evaporated tungsten is redeposited back onto the filament in a rate
that increases with filament temperature. This is because of the relatively greater
thermal stability of tungsten fluoride as compared to the other tungsten halides.
In effect, the fluorine cycle renders the filament much more stable because the hot
spots, which are more prone to evaporation, are also significantly more effective
in thermally breaking down tungsten fluoride and thereby depositing tungsten back
onto the filament. In pactice, it is found that, at hot spots, tungsten deposition
occurs at a higher rate than does evaporation, and the net effect is for a fluorine-cycle
lamp to continually repair its filament.
[0005] The attractiveness of the fluorine cycle in incandescent lamps is somewhat offset
by the toxicity of fluorine compounds (either initially or after operation of the
lamp) and the technical difficulty of providing a lamp vessel and lead wires that
are resistant to fluorine attack. U.S. Patent No. 4,256,988, e.g., addresses the problems
of how to protect a lamp envelope and the filament supporting structure from attack
by fluorine in a tungsten-fluorine lamp. The suggested method involves coating the
interior of the lamp envelope and the internal structure with fluorine resistant compounds.
[0006] While this approach is interesting, it would certainly be expensive; and, it does
not solve the problems occasioned by leaving in the hands of consumers a vessel loaded
with toxic fluorine or fluoride compounds.
DICLOSURE OF THE INVENTION
[0007] It is, therefore, an object of the invention to obviate the disadvantages of the
prior art.
[0008] It is another object of the invention to enhance the life of tungsten filaments.
[0009] These objects are accomplished, in one aspect of the invention, by the provision
of a method for increasing the life of tungsten filaments. The method comprises the
steps of forming a tungsten filament and then burning the filament in a tungsten fluoride
containing atmosphere to substantially remove hot spots. The filament is subsequently
assembled into a lamp vessel or envelope having an atmosphere that does not contain
fluorine.
[0010] This process allows the use of the advantageous fluorine regenerative cycle under
closely controlled manufacturing conditions while keeping the ultimate lamp delivered
to the general public fluorine-free.
BEST MODE FOR CARRYING OUT THE INVENTION
[0011] For a better understanding of the present invention, together with other and further
objects, advantages and capabilities thereof, reference is made to the following dislosure
and appended claims.
[0012] The method is accomplished by first forming a filament from a length of tungsten
wire. The filament can remain as cut; or it can be formed into a coil; a coiled coil;
or any other desired configuration. The filament is then placed in closed environment
which can be the final lamp vessel but preferably is a separate chamber formed of
monel or other suitable fluorine resistant material.
[0013] The closed environment is then provided with a gas fill which includes tungsten fluoride
(WF
6). Electrical energy is then applied to the filament to cause the filament to incandesce.
The time and operating conditions should be sufficient to allow substantial repair
of hot spots, wherever located or regardless of cause. This fluorine treatment, as
noted above, renders the filament more stable.
[0014] After the treatment the filament is removed from the closed environment and subsequently
is assembled into a lamp. The treated filament is effective in vacuum incandescent
lamps, inert-gas filled incandescent lamps, such, for example, as lamps containing
an argon-nitrogen fill, and tungsten-halogen lamps containing a halogen other than
fluorine.
[0015] The gas fill for the closed environment is preferably a mixture of.an inert gas,
such as nitrogen, and up to about 50% WF
6.
[0016] Employment of this process thus provides the benefits of the fluorine cycle on initial
filament repair while allowing the sale to the public of lamps which do not contain
fluorine.
[0017] While there have been described what are at present considered to be the preferred
embodiments of the invention, it will be apparent to those skilled in the art that
various changes and modifications can be made herein without departing from the scope
of the invention as defined by the appended claims.
1. In a method of increasing the life of tungsten filaments employed as a light emitting
element in a lamp, the steps comprising: forming a filament from a length of tungsten
wire; placing said filament in a closed environment; providing said closed environment
with a gas fill which includes tungsten fluoride; applying sufficient electrical energy
to said filament to cause said filament to incandesce; maintaining said filament at
incandescence for a sufficient period of time to substantially remove hot spots from
said filament; withdrawing said electrical energy and removing said filament from
said closed environment; and subsequently operatively sealing said filament in a lamp
envelope having a fluoride-free atmosphere.
2. The method of Claim I wherein said gas fill includes also nitrogen.
3. The method of Claim 2 wherein said gas fill comprises up to about 50% tungsten
fluoride.
4. The method of Claim 1 wherein said lamp envelope contains a substantial vacuum.
5. The method of Claim 1 wherein said lamp envelope contains an inert gas.
6. The method of Claim 1 wherein said lamp envelope contains a halogen selected from
chlorine, bromine and iodine.