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Publication numberUS2805134 A
Publication typeGrant
Publication dateSep 3, 1957
Filing dateDec 15, 1954
Priority dateDec 15, 1954
Publication numberUS 2805134 A, US 2805134A, US-A-2805134, US2805134 A, US2805134A
InventorsStrange John P
Original AssigneeMine Safety Appliances Co
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Combustible gas indicator and filament therefor
US 2805134 A
Abstract  available in
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Claims  available in
Description  (OCR text may contain errors)

Se t. 3, 1957 J. P. STRANGE 2,805,134

COMBUSTIBLE GAS INDICATOR AND FILAMENT THEREFOR Filed Dec. 15, 1954 IN VEN TOR. JOHN R STRANGE.

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14 TTO/QNE 7 5 United States Patent COMBUSTIBLE GAS INDICATOR AND FILAMENT THEREFOR John P. Strange, Murrysville, Pa., assignor to Mine Safety Appliances Company, Pittsburgh, Pa., a corporation of Pennsylvania Application December 15, 1954, Serial No. 475,510

4 Claims. (Cl. 23-255) This invention relates to combustible gas indicators of the hot wire type. Such devices usually embody two filaments in an electrical circuit which heats them to a temperature such as to cause combustion of a combustible constituent of a gas passed over one of the filaments, commonly known as the detector filament. The other filament is exposed to air free from combustible constituents or to an inert atmosphere, such as nitrogen, and this filament is commonly referred to as the compensator filament. The two filaments are associated in an initially balanced electrical circuit. When a gas is to be tested for the presence of combustible constituent it is passed over the heated detector element and the resultant burning of the combustible constituent at the surface of the filament causes its temperature to increase with concurrent increase of its electrical resistance. That in-turn results in unbalance of the circuit, which indicates the presence of a combustible constituent, and by appropriate calibration of the recording instrument the amount of the combustible constituent is indicated directly.

To provide suflicient mechanical strength and stability for these filaments, the end supports must be constructed of relatively large size, possibly ten to fifteen times the diameter of the filament wire. Heat is conducted away from the ends of the filament to the relatively large mass of such supports. In good filament design some advantage is taken of the mutual exchange of heat between individual turns of a coiled filament but even in the best designs the center turns of the helix are much hotter than those near the ends, with the mid-section at the highest temperature.

The rate.- of evaporation of the filament metal, commonly platinum, increases very rapidly with temperature, and in order to. provide suflicient sensitivity when detecting combustibles of high ignition temperature or to pre vent poisoning by such contaminants as tetr-aethyl lead or silicones it is'necessary to have the major portion of the filament operate at a relatively high temperature. This automatically brings the center portion of the filament to a temperature which is sufficiently high as to make the life of the filament short and to cause premature burnout. Furthermore, when; operated at such high temperatures burnout 'of the filament almost invariably follows exposure to high concentrations of combustible gas or vapor. Such difliculties are particularly true of filaments for portable instruments where power for the circuit must be supplied by batteries and hence minimum power consnmption is required which in turn necessitates the use of very fine wire for the filament.

An object of the invention is to provide combustible gas indicators of the hot wire type of any conventional or desired construction but which embody a novel form of filament characterized by longer useful life than the filaments used heretofore.

A particular object is to provide filaments for hot wire combustible gas indicators that operate over longer-periods of time under comparable conditions than the filaments used before while possessing satisfactory sensitivity,

that may be prepared easily and inexpensively, and that form a desirable substitute, or replacement, for the previously used filaments in existing apparatus of the type contemplated.

'Still another object is to provide a simple, easily performed and inexpensive method of preparing filaments in accordance with the immediately preceding object.

Other objects will appear from the following specification.

The invention will be'described in connection with the accompanying drawings in which:

Fig. 1 is a diagrammatic representation of one common form of combustible gas indicator of the hot wire type;

Fig. 2 is a longitudinal somewhat schematic sectional view on an enlarged scale through a detector element of an instrument of this type; and

Fig. 3 is a cross-sectional view taken on line IH-III, Fig. 2, but on a still larger scale, showing a filament in accordance with this invention but with portions exaggerated for readiness of understanding.

Combustible gas indicators of the hot wire type take a variety of forms. A common form is that shown in Fig. 1. It comprises a coiled filament I mounted within a housing 2 provided with an inlet 3 and an outlet 4 for circulation over the filament of a gas to be tested. A similar filament 1a is mounted within a closed housing 2a containing air or an inert gas. Filaments 1 and 10 constitute, respectively, the detector and compensator elements and they are connected, as shown, as the arms of one branch of a Wheatstone bridge, the other branch of which comprises resistances 5 and 5a, as known in the art. Power is supplied to the circuit from a battery 6. The branches are bridged by a null instrument 7, such as a galvanometer, and a variable resistance 8 is provided for bringing the circuit into balance. In another well known type of hot wire instrument the filaments are connected in a potentiometer circuit instead of in a Wheatstone bridge, as is so well known in the art as not to require illustration. Typical forms of such combustible gas indicators are represented by Patents Nos. 2,114,383, 2,149,441, 2,219,391, 2,244,366, 2,279,397, 2,378,019, and 2,393,220, although various other modifications and refinements appear in numerous other patents.

As shown in Fig. 2 leads to the filaments pass through insulated bushings 9 disposed in opposed ends of the housing, and the coiled portion of the filament is secured in the binding posts 10.

The present invention isv predicated upon my discovery that filaments of improved life, i. e., reduced tendency toward burning out, under the conditions described above, are provided by coating the mid-section of the filament, most suitably in the form of 'a helix, with a thin, adherent coating of glass. Thus, as seen in Fig. 3, the filament 1 of platinum is coated with glass 11. K

The exact width of the coating band is determined by the protection desired and the decrease in filament sensitivity that can be tolerated. For most purposes, however, only a v'erynarrow band at the mid-section need be coated. As an example, but not by way of limitation, I have found that for a'filament of platinum wire of 0.002- inch diameter wound in the form of a helix with 15 turns and an internal diameter of 0.005 inch, covering the center two turns prevents burnout for as many as 50 exposures to the maximum explosive. concentration of natural gas orpetroleum vapor in air. The decrease in sensitivity of such a coated filament when treated in the manner described below is only a few per cent from the sensitivity of an untreated filament. V

Suchfilamentscoated at the mid-section-with a narrow band of'glass are utili-zable not only in new instruments but also as replacements for the filaments of allexis ting forms *of combustion gas indicators. Likewise, although burning out is not fully understood but without limiting myself to this explanation I now believe that it may be due to any or all of the following factors. Since the burning of gas or vapor is promoted by the catalytic action of the metal, such as platinum, the glass prevents contact of the metal and the combustible constituent in the area that is normally hottest and so inhibits burning in that area and keeps that section at a lower temperature than would be attained with an unprotected filament. The glass possibly acts also to prevent escape of vapor of the filament metal and so decreases the rate of evaporation at the normally hottest center section. Even though glass is a relatively poor conductor of heat it probably aids in the transfer of heat from the center to the adjacent turns in the case of a coiled filament and so reduces the temperature of the normally hottest center turns. A further factor is that the glass gives physical support, or strengthens, the center section and helps to prevent separation of the wire in that point as the melting point of the metal is approached.

It has been found that with the small amount of glass used to give the desired protection, no measurable increase in power is required to maintain the filament at the same average temperature as the normal operating temperature of an untreated filament, This indicates that the rate of total heat loss is unchanged in the filaments of this invention in comparison with untreated filaments. The decrease in heat loss by radiation, conduction and convection at the center is compensated for by greater conduction to the ends and greater surface area.

Experience has shown that only a very thin layer of glass coating is necessary to provide the protection and increased life that characterizes filaments in accordance with this invention. The glass coating may be applied in a variety of ways although I now prefer to do so with the aid of a low power microscope in the following manner. The filament is heated so that the mid-section temperature is above the melting point of the glass used. Soft glasses have been used successfully but whatever glass is used must, of course, have a melting point above the maximum temperature to which it will be exposed in the use of the filament. Most suitably the glass is in the form of a fine filament or bundle of fibers, with a cross section of about 0.005 inch. It may be strung across a bow of suitable wire, such as No. 28 brass, for convenience of manipulation, and it is touched to the center of the heated wire helix to cover the desired band width and apply the desired thickness.

Another convenient way is to use a micro-manipulator adjustable in three dimensions to feed the glass fiber into the heated helix. One end of the fiber is attached to the manipulator by suitable adhesive material, such as cement or modeling clay, and the fiber is fed at a right angle to the axis of the helix into the center turn. As it touches the heated wire the glass melts and forms a small bead attached to the Wire, and by means of the manipulator the glass of the head can be moved and positioned as desired.

Most suitably, filaments prepared in accordance with the invention are given a conditioning treatment to restore most of the sensitivity which results from the decrease or metal surface. This is accomplished by exposing the glass while molten to a mixture of a combustible gas or vapor in air. One or two exposures to a maximum explosive concentration of natural gas in air has been found effective although other gas mixtures containing combustible constituents may be used likewise. This treatment gives the glass coating a fritted or sintered appearance.

The sensitivity of the filament is restored in this way.

almost to its untreated value while still maintaining protection against burnout. The glass apparently takes on the fritted appearance due to the presence of combustion products of the combustible gas or vapor burning on its surface while it is in the molten state. Heating the filament to the same temperature by passing an electrical current through it but in the absence of a combustible gas or vapor does not give the glass the same appearance and in fact will restore it to the glassy state if done after the gas conditioning treatment.

As indicated above, in the case of instruments having both detector and compensator filaments it is desirable to coat both filaments in accordance with the invention. This is desirable in order that the compensator shall' operate at the same temperature as the detector to achieve maximum compensation for bridge voltage variations, ambient temperature changes, and the like. Also, the effects of aging would thus be more nearly the same for both arms of the bridge, thereby minimizing zero drift with use. l

Although the invention has been described with particular reference to two-filament instruments, it will be understood that it is applicable equally to single filament indicators such, for example, as that described in the R. E. Hartline Patent No. 2,279,397.

Although the invention has been described with specific reference to coating with glass, it will be understood that other glassy or glass-like materials may be used likewise, an example being sodium silicates.

According to the provisions of the patent statutes, I have explained the principle of my invention and have illustrated and described what I now consider to represent its best embodiment. However, I desire to have it understood that, within the scope of the appended claims, the invention may be practiced otherwise than as specifically illustrated and described.

I claim: 1

1. In a combustible gas indicator comprising a detector filament, means for passing gas to be tested over said filament, a source of electric current associated with said filament for heating it to a predetermined temperature, and electrical means responsive to'increase of temperature of said filament due to the presence of a combustible constituent'in said gas; the improvement consisting in providing said detector filament as a metallic wire having a narrow band at the mid-section surrounded by a thin and adherent coating of glass the melting point of which is above the temperature at which the detector filament is operated.

2. An indicator according to claim 1, said detector filament being a platinum coil, and said glass being soft glass.

3. In a combustible gas indicator comprising a detector filament, a compensator filament, means for passing gas to be tested over said detector filament, a source of electric current associated with said filaments for heating them to a predetermined temperature, and electrical means responsive to increase of temperature of said detector filament due tothe presence of a combustible constituent in said gas, the improvement consisting in provid ing said filaments as metallic wires each having a narrow band at the mid-section surrounded by a thin and adherent coating of glass the melting point of which is above the temperature at which the detector filament is operated.

4. An indicator according to claim 3, said filaments being platinum coils, and said glass being soft glass.

References Cited in the file of this patent ,UNITED STATES PATENTS 2,529,971 Schmidinger Nov. 14, 1950

Patent Citations
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US1582145 *Jul 17, 1924Apr 27, 1926ShoenbergLighter
US1619318 *Jan 19, 1920Mar 1, 1927Magnavox CoElectrostatic detector and amplifier
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US2396196 *May 15, 1943Mar 5, 1946Bell Telephone Labor IncControllable resistor
US2529971 *Jul 31, 1946Nov 14, 1950Schmidinger JosephMethod and apparatus for the production of bead and wire assemblies
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3221320 *Mar 9, 1962Nov 30, 1965Komyo Rikagaku Kogyo KabushikiGas alarm circuit
US3311455 *Apr 30, 1963Mar 28, 1967Barton Instr CorpDetector for combustible gas
US3315517 *Mar 19, 1964Apr 25, 1967Bodenseewerk Perkin Elmer CoThermal conductivity detector cell
US4313907 *Apr 21, 1980Feb 2, 1982National Mine CorporationApparatus for the detection of a combustible gas
US5055266 *Mar 23, 1990Oct 8, 1991Arch Development CorporationNoble metal; catalytic electrochemical conversion of pollutant producing electrical signals
US5360266 *Jun 18, 1993Nov 1, 1994Robert Bosch GmbhControl and analysis circuit device for measuring reaction heat
US5880354 *Jun 11, 1997Mar 9, 1999Cts CorporationGas sensor with orientation insensitivity
Classifications
U.S. Classification422/97, 73/25.1
International ClassificationG01N27/14, G01N27/16
Cooperative ClassificationG01N27/16
European ClassificationG01N27/16