Measuring and testing – Gas analysis – Gas of combustion
Reexamination Certificate
2001-05-03
2002-09-03
Larkin, Daniel S. (Department: 2856)
Measuring and testing
Gas analysis
Gas of combustion
C422S174000
Reexamination Certificate
active
06442994
ABSTRACT:
BACKGROUND OF THE INVENTION
Field of the Invention
This invention relates to an instrument and a method for the detection of combustible gases or vapours in air.
In particular, although not exclusively, the present invention has reference to catalytic bead sensors intended for such detection and also to the method of their usage. It is to be understood, however, that the invention also has reference to combustible gas sensors in general, for example metal oxide semiconductor type sensor, field effect transistor sensors and others.
Conventional catalytic bead sensors used for the detection of combustible gases of vapours in air incorporate an electrically heated platinum coil embedded within a detector bead comprising a porous ceramic support containing a suitable catalyst component impregnated within its pores. At an appropriate temperature the gas or vapour to be measured reacts (combusts) with oxygen from the air at the catalyst surface within the bead. Heat evolved by this reaction increases the temperature of the bead and consequently the electrical resistance of the platinum coil embedded within the bead. This change in resistance provides a measure of the amount of combustible gas or vapour in the atmosphere under test.
In a complete device, a second compensator bead is also employed to compensate for changes in ambient conditions such as temperature, humidity etc., which could provide erroneous readings. The compensator bead is rendered inactive to the combustion reaction but being in all other respects closely similar in structure to the detector bead, it responds similarly to ambient conditions such as temperature, humidity etc and its output can therefore be used to subtract any such extraneous effects from the signal obtained from the detector bead. The matched pair of detecting and compensating beads is conveniently employed in a Wheatstone Bridge measurement circuit providing a signal which is proportional to the concentration of combustible gas or vapour in the atmosphere under test. The detector and compensator beads are known as pellistors, see E. Jones, ‘The Pellistor Catalytic Gas Detector’ in ‘Solid State Gas Sensors’, edited by P. T. Moseley and B. C. Tofield, 1987 (ISBN 0-85274-514-1).
A problem which can arise with known pellistor bead devices is that they can be poisoned by certain gases or vapours to which the detector bead may be exposed, see S. J. Gentry & P. T. Walsh, ‘The Theory of Poisoning of Catalytic Flammable Gas-sensing Elements’, in Solid State Gas Sensors, edited by P. T. Moseley and B. C. Tofield, 1987 (ISBN 0-85274-514-1). The poison resistance of a conventional catalytic bead detector largely depends upon the surface area of catalyst within the bead. When poisons such as silicone vapours access the heated catalyst surface it is thought that the silicones adsorb on the catalyst surface where they decompose thermally to silica which forms an overlayer which progressively blocks the active catalyst sites. As this process continues the signal from the element decreases until the element is rendered inactive to combustible gases such as methane. This process is irreversible.
Other gases such as hydrogen sulphide also reduce the output from pellistor detector beads by being thermally decomposed on the catalyst surface to form blocking films (such as sulphur or solid sulphides) but in these instances the process can be reversed by raising the temperature of the element temporarily to drive off the blocking film; these substances are therefore referred to as inhibitors rather than poisons. Nevertheless their effects are detrimental to the instrument operation and especially if the circumstances are such that it is not possible to increase the detector bead temperature to reactivate the bead, for example if the degree of inhibition is very significant during use in a duty period before it is subjected to a recalibration.
Another drawback with the use of pellistor devices, particularly with portable instrument operation, is that the pair of matched detector/compensator beads requires power to maintain the temperature of the beads. Typical bead temperatures of conventional devices for methane detection are about 500 degrees centigrade and power requirements are around 150 to 200 mW per bead (0.3 to 0.4 watts per matched pair). Some larger beads designed for use where poison resistance is of major importance have even greater power requirements, up to 1.2 watts per pair. The latter are not normally used in portable applications but even the lower power sensors have substantial battery requirements in portable instruments.
SUMMARY OF THE INVENTION
An object of the present invention is to provide an improved method and an instrument for the detection of combustible gases or vapours in air.
According to a first aspect of the invention, a method for the detection of combustible gases or vapours in an atmosphere using a sensor, includes the steps of exposing the sensor to the atmosphere, sensing the atmosphere for the level of oxygen, activating the sensor responsive to a predetermined level of oxygen change indicating the presence of a contaminant gas or vapour, detecting the level of combustible gases or vapours in the atmosphere using the sensor, and maintaining the activation of the sensor or deactivating the sensor dependent upon the level of contaminant gases of vapours detected.
According to a second aspect of the invention a method for the detection of combustible gases or vapours in an atmosphere using pellistors comprising a detector bead and a compensator bead, includes the steps of exposing the pellistor to the atmosphere, sensing the atmosphere for the level of oxygen, activating the pellistors responsive to a predetermined level of oxygen change indicating the presence of a contaminant gas or vapour, detecting the level of combustible gases or vapours in the atmosphere using the pellistors, and maintaining activation of the pellistor or deactivating the pellistors dependent upon the level of contaminant gases or vapours detected.
The activation of the sensor or the pellistors may be on a continuous basis or cyclical on an on/off basis.
According to a further aspect of the invention an instrument for the detection of combustible gases or vapours in an atmosphere, includes a sensor for the combustible gas, an oxygen sensor adapted to sense a change in the level of oxygen in the atmosphere, and control means for controlling the activation of the sensor responsive to the sensed level of oxygen in the atmosphere falling below a predetermined reference level of oxygen.
According to a further aspect of the invention an instrument for the detection of combustible gases or vapours in an atmosphere, includes pellistors comprising a detector bead and a compensator bead, an oxygen sensor adapted to sense a change in the level of oxygen in the atmosphere, and control means for controlling activation of the pellistors responsive to the sensed level of oxygen in the atmosphere falling below a predetermined reference oxygen level.
The control means or other means may be adapted to effect activation and to maintain activation of the sensor or pellistors on a continuous basis or on a cyclic on/off basis in the event that combustible gas is detected.
The instrument is provided with a power source which may be mains or battery operated.
The oxygen sensor may be an electrochemical oxygen sensor which is self-powered, for example of a type described in UK Patent 1 571 282. The oxygen sensor may be maintained constantly in an active mode, there being little power consumption attributable to this activity.
In clean dry air, the oxygen sensor provides a reference reading equivalent to 20.9% oxygen. When any other substance is present it dilutes the ambient oxygen below the predetermined reference level and produces a reaction in the oxygen sensor output. The change in oxygen reading triggers the instrument to activate the pellistor to determine whether the change is due to the presence of a combustible substance. By virtue of the invention the pellistor is only act
BW Technologies Limited
Larkin Daniel S.
McMurry Michael B.
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