Gas lantern with ignition system

A automatic ignition gas lantern includes baffle positioned near the outside of a mantle, so that gas flowing out of the mantle will be disturbed by the baffle. This sets up a region with a fuel/air mixture that can be easily and reliably ignited. A spark is then generated in this region, which ignites the gas and causes the mantle to glow brightly.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to the field of lanterns that use compressed-gas 
fuel. More specifically, it relates to lanterns that include a gas-flow 
baffle to create, in the vicinity of the baffle and a mantle used with the 
lantern, a region having a fuel/air mixture that can be easily ignited. 
Once this region is established, it is ignited with a spark. 
2. Description of Related Art 
Lanterns that use compressed-gas fuel have been available for some time. To 
operate this type of lantern, the user connects the lantern to a source of 
compressed gas, such as a tank of propane. For ease of discussion, the 
invention is explained below using propane gas as an example. It is to be 
understood, however, that other suitable gases (including butane and 
mixtures of gases) may be used instead. The user then opens a valve, which 
allows the fuel to flow through a burner assembly and into a mantle, which 
is porous. 
Traditionally, these lanterns are lit manually by holding a lit match near 
the outside of the mantle. When the gas escapes through the mantle and 
reaches the flame from the match, the gas starts to burn, which causes the 
mantle to glow brightly. 
Lighting match-lit lanterns, however, can be cumbersome and inconvenient, 
particularly when it is dark outside. This type of lantern also suffers 
from a number of other disadvantages, including the inability to light the 
lantern if the user forgets to bring along matches, or if the matches get 
wet. In addition, because the mantle is extremely fragile, there is a 
significant risk that the mantle will be accidentally broken by the match. 
To alleviate some of the problems associated with match-lit lanterns, 
various mechanisms have been proposed and implemented. For example, the 
Coleman Company Inc. makes a propane lantern, Model 5154B700T, with an 
electronic ignition system. 
FIG. 1 is a schematic representation of the major components of that 
lantern. To operate that lantern, the user turns control knob 18 which 
opens a fuel valve 19 and releases gas into the burner 11. The gas mixes 
with air in the burner 11 and the fuel/air mixture flows out of the gas 
outlet 13 and into the mantle 14, and begins to escape through the porous 
mantle. In addition to opening the valve 19, turning the control knob 18 
also actuates a piezoelectric spark generator 17. This spark generator 17 
causes a spark to jump from a first electrode 15 to a second electrode 16. 
The first electrode is shaped like a blade and is about 3 cm long, 5 mm 
high, and 1 mm thick. Because these electrodes are positioned close to the 
outside of the mantle 14, the spark will ignite the gas escaping from the 
mantle 14, which causes the mantle. to glow. 
Lanterns with electronic ignitions are significantly more convenient than 
the match-lit lanterns described above. With existing electronic ignition 
lanterns, however, sometimes the spark fails to light the lantern, 
particularly when the lantern is cold. Although the inventor has not 
performed any experiments to verify the reason, it may be because the gas 
in the vicinity of the mantle is moving relatively fast and has very 
little turbulence, which makes it difficult to ignite with a spark. 
When the lantern does not light, the user can adjust the position of the 
electrodes and try to light the lantern again. Alternatively, the user can 
light the lantern using a match. But using these backup procedures is 
inconvenient, and therefore defeats the main advantage of the automatic 
ignition lanterns. 
U.S. Pat. No. 3,843,311 describes some of the difficulties of lighting a 
lantern by providing a spark outside of the mantle. It also describes a 
system which claims to improve the lighting operation by generating a 
spark inside the mantle. It is, however, relatively difficult to 
manufacture lanterns that create sparks inside the mantle. 
SUMMARY OF THE INVENTION 
Accordingly it is an object of this invention to provide a lighting 
mechanism exterior to the mantle that increases the probability of 
lighting the lantern and is easy to manufacture. 
According to one aspect of the invention, a gas lantern which operates 
using a mantle is provided. The mantle may be purchased separately, or 
packaged together with the lantern. The lantern includes a burner having a 
gas outlet and two electrodes. The first electrode has a baffle section 
positioned so that when the mantle is disposed about the gas outlet, gas 
flowing out of the mantle will interact with an active surface of the 
baffle section to establish an ignition region having a fuel/air mixture 
that can be easily ignited. The second electrode is positioned so that a 
spark gap is formed between the second electrode and the baffle section of 
the first electrode, with the spark gap located in the ignition region. 
The lantern also includes a spark generator that, when actuated, creates a 
spark across the spark gap. 
According to another aspect of the present invention, a gas lantern which 
operates using a mantle is provided. The lantern includes a burner having 
a gas outlet and a baffle positioned so that when the mantle is disposed 
about the gas outlet, gas flowing out of the mantle will interact with an 
active surface of the baffle to establish an ignition region having a 
fuel/air mixture that can be easily ignited. The lantern also includes a 
first electrode and a second electrode positioned so that a spark gap is 
formed between the second electrode and the first electrode, with the 
spark gap located in the ignition region. The lantern also includes a 
spark generator that, when actuated, creates a spark across the spark gap. 
According to yet another aspect of the present invention, a gas lantern 
which operates using a mantle is provided. The lantern includes a burner 
having a gas outlet and a baffle positioned so that when the mantle is 
disposed about the gas outlet, gas flowing out of the mantle will be 
deflected by an active surface of the baffle to establish an ignition 
region having a fuel/air mixture that can be easily ignited. The active 
surface has an area of at least about 20 square mm. The lantern also 
includes a first electrode and a second electrode positioned so that a 
spark gap is formed between the second electrode and the first electrode, 
with the spark gap located in the ignition region. The lantern also 
includes a spark generator that, when actuated, creates a spark across the 
spark gap. 
When a baffle is used in accordance with the present invention, and a spark 
is fired into the fuel/air mixture near the baffle, a very high ignition 
success rate can be achieved. Although Applicant has not performed any 
experiments to explain this success, it is believed that by providing a 
baffle near the place the gas leaves the mantle, the gas is slowed down 
and turbulence is introduced, forming an ignition region with an easily 
ignitable fuel/air mixture.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
FIG. 2 is a view of a lantern in accordance with a preferred embodiment of 
the present invention, assembled together with other components such as a 
mantle 24, a gas tank 31, a safety cage 32, a ventilator 33, and a handle 
34. In the illustrated combination, the lantern is ready for use. 
FIGS. 3A and 3B are two side elevations, from different angles, of a 
lantern in accordance with a preferred embodiment of the present 
invention. In FIG. 3B, a mantle 24 is installed on the lantern. When the 
lantern is connected to the fuel supply (not shown) the control knob 28 
turns a valve (not shown) that controls the flow of fuel into the lantern. 
One of the most popular fuels for this type of lantern is compressed 
propane gas, which is typically provided in a small fuel cylinder (or 
tank). 
When the lantern is connected to the fuel supply (in any conventional 
manner) and the control knob 28 is turned to open the fuel valve, the 
propane flows out of the supply tank and into the burner 21. The propane 
mixes with air and flows through the burner 21 and out of the gas outlet 
23. Ordinarily, a mantle 24 will be tied or clipped onto the gas outlet 23 
so that the gas flowing out of the gas outlet 23 will flow into and 
through the mantle 24. The mantle 24 is formed of a screen-like material, 
with many small holes (not shown). The gas flows out of the tiny holes in 
the mantle 24 and escapes into the environment. Normally, the propane 
leaving the mantle will tend to flow downward, primarily because of the 
initial downward velocity of the gas escaping from the pressurized tank. A 
secondary cause for this downward flow is that propane is heavier than 
air. 
An igniter tab 25 is installed near the bottom of the mantle 24. The 
igniter tab 25 includes a baffle section 25a. When gas flowing out of the 
mantle arrives at the baffle section 25a, it impinges on active surface of 
the baffle section 25a, which disturbs the ordinary flow of gas. 
Preferably, the active surface has an area of at least about 20 square mm, 
and more preferably at least about 40 square mm. While it is believed that 
the baffle section 25a slows the gas down and introduces turbulence into 
the gas stream, the exact nature of the disturbance has not been 
experimentally verified. However, it has been demonstrated to form a 
fuel/air mixture in the vicinity of the baffle section 25a that can be 
easily and reliably ignited. The region of this fuel/air mixture is called 
the ignition region. Preferably, the igniter tab 25 (including the baffle 
section 25a) is made of a conductive material such as metal and also 
serves as the first electrode, as explained below. 
In one preferred embodiment, the baffle section 25a at the end of the 
igniter tab 25 is curved to provide a half-cylindrical face. This shape 
reduces the probability of a mantle being snagged or torn on a sharp edge 
of the baffle section 25a while being installed. This shape also provides 
a baffle section 25a that can interfere with the flow of gas arriving from 
the side as well as gas arriving from above, which may improve the 
baffling effect. A preferred radius for the cylinder is between about 2 mm 
and about 4 mm, although other radii may be used as well. While a 
half-cylindrical face is preferred, other part-cylindrical faces (e.g. a 
quarter cylinder) may be used instead. 
Alternatively, non-cylindrical shapes may be used. For example, in another 
preferred embodiment, the igniter tab shown in FIGS. 3A, 3B, and 5A 
through 5D is replaced with a flat igniter tab 61 (shown in FIG. 6). In 
this embodiment, the active surface of the baffle section 62 is flat and 
substantially perpendicular to the downward flow of gas arriving at the 
baffle section 62. 
Once a suitable ignition region has been established in the vicinity of the 
baffle section, the fuel/air mixture can be easily ignited by a spark. 
A spark gap is established by placing a second electrode 26 a short 
distance away from the baffle section 25a of the igniter tab 25. 
Preferably, this spark gap is between about 1 and about 5 mm, and most 
preferably about 3 mm long. Larger spark gaps of up to 1 cm or even longer 
may also be used, provided that a spark generator capable of jumping the 
spark gap is used. 
The spark gap may be positioned to spark to the edge of the baffle section 
25a, as shown in FIGS. 3A and 3B. This is also illustrated in FIG. 7, 
which is a top view of a preferred arrangement for the mantle 24, igniter 
tab 25, and second electrode 26. Alternatively, the spark gap may be 
positioned to spark to the active face of the baffle section 25a by moving 
the second electrode closer to the middle of the active surface. 
FIG. 4 is a schematic representation of the major components of a lantern 
in accordance with a preferred embodiment of the present invention. The 
igniter tab 25 serves as the first electrode, and is electrically 
connected to one terminal of the spark generator 27. The other terminal of 
the spark generator is electrically connected to the second electrode. 
When actuated, the spark generator 27 generates a spark between the second 
electrode 26 and the baffle section 25a of the first electrode, i.e., the 
igniter tab 25. 
When a metal burner is used, a direct wired connection between the spark 
generator and the first electrode is not required. Instead, the first 
electrode 25 may be welded (e.g., spot welded or brazed) to the burner, 
and the spark generator may be electrically connected to another spot on 
the burner 21. The burner 21 will then conduct the electricity to the 
first electrode 25. The second electrode 26 may be insulated from the body 
of the lantern as described in U.S. Pat. No. 4,691,136, which is 
incorporated herein by reference. 
The user actuates the spark generator 27 using a suitable actuator such as 
control knob 28. The spark generator 27 then induces a voltage difference 
between the second electrode 26 and the first electrode 25. Because the 
first electrode is connected to the metal burner, it serves as an 
electrical ground. When this voltage difference reaches a sufficient 
level, a spark jumps across the spark gap. Because the second electrode 26 
is closer to the baffle section 25a than to any other part of the first 
electrode, i.e., the igniter tab 25, the spark will always jump to the 
baffle section 25a. 
The spark generator 27 may be a conventional piezoelectric device. While 
piezoelectric spark generators are preferred, the particular type of spark 
generator is not critical to the present invention, and other types of 
spark generators may be used as well. 
The spark generator 27 may be actuated by the rotation of the same control 
knob 28 that allows the gas to flow into the burner, in a conventional 
manner. One suitable mechanism for providing this feature is disclosed in 
U.S. Pat. No. 4,870,314, which is incorporated herein by reference. It 
describes a cam mechanism for actuating a pushbutton piezoelectric 
ignition device when a control knob is rotated. This feature allows a 
single control knob to control both the flow of gas and the ignition. 
When the spark generator is actuated, the spark will jump the spark gap and 
ignite the fuel/air mixture that is established in the ignition region (as 
described above), which lights the lantern. 
FIGS. 5A, 5B, 5C, and 5D are detailed views showing, respectively, 
perspective, rear, top, and side views of a preferred igniter tab 25 in 
accordance with the present invention. 
It has been found that a lantern made in accordance with the present 
invention will almost always light on the first spark when the lantern is 
hot, and on the first or second spark when the lantern is cold. 
While the present invention has been described with reference to specific 
embodiments, numerous alternative embodiments may be substituted for those 
described above, as will be appreciated by those skilled in the art. For 
example, instead of using a conducting igniter tab to both baffle the flow 
of gas and serve as the first electrode, as described above, the invention 
can be implemented using a first electrode that is not integral to the 
baffle. One way to accomplish this would be to use the igniter tab 
described above to baffle the gas, but to draw a spark to an independently 
provided electrode with its tip located in the ignition region. 
In the embodiment shown in the drawings, the mantle has an opened end at 
the top and a closed end at the bottom. The fuel/air mixture enters the 
mantle from the top end and flows through the holes in the mantle, and the 
baffle section is located below the bottom end of the mantle. In an 
alternative preferred embodiment, the baffle may be moved up as high as 
the half-way point between the two ends of the mantle, or even higher up. 
In another alternative embodiment, the mantle could be inverted, with the 
gas outlet located below the mantle so that the fuel air mixture shoots 
into the mantle from the bottom. In yet another alternative embodiment, 
the conventional closed-end mantle shown in the figures could be replaced 
with a conventional mantle of the type that is opened at both the top and 
the bottom. 
The individual components designated by blocks in the drawings are all 
known in the lantern arts and their specific construction and operation 
are not critical to the operation or best mode for carrying out the 
present invention. 
It is to be understood that the invention is not limited to the specific 
embodiments described above, and that various changes and modifications 
can be effected without departing from the scope or spirit of the present 
invention.