Heater patterns for planar gas sensors

Measuring and testing – Gas analysis – By thermal property

Reexamination Certificate

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Details

C073S023320, C073S031050, C338S034000, C422S094000, C029S595000, C029S611000

Reexamination Certificate

active

06435005

ABSTRACT:

TECHNICAL FIELD
This disclosure relates to planar gas sensors, and, more particularly, to heater patterns for planar gas sensors that yield a reduction in the incidence of cracking attributable to tensile stresses at the edges of the planar gas sensors.
BACKGROUND
Gas sensors, and in particular oxygen sensors are used in combustion engines to control the air/fuel ratio in the combustion chamber so that the air/fuel ratio remains at or near its proper stoichiometric value. Maintaining the proper stoichiometric value, allows for the improvement of fuel consumption and the minimization of pollutants in an exhaust gas. An oxygen sensor typically includes an oxygen sensing element having an ion-conductive solid electrolytic plate on which porous electrodes are disposed. A difference in potential corresponding to the difference in oxygen content between the exhaust gas and the reference air is generated by the oxygen sensing element, is quantified, and is used to adjust the air/fuel ratio in the combustion chamber.
The proper functioning of the oxygen sensing element is typically dependent upon its temperature. Because a significant amount of time is often required for the oxygen sensor to become heated to operating temperature after startup of the engine, the air/fuel ratio is difficult to control during that time. Heaters are, therefore, oftentimes incorporated into the oxygen sensing system to more quickly bring the oxygen sensing elements up to a temperature at which the most efficiency can be realized.
Typical heaters in planar sensors are formed in various patterns on one face of the oxygen sensing element. Such designs attempt to create a uniform temperature profile across the sensor element by adjusting the heat input through patterning of a single heater trace. Heater patterns such as these are difficult to control because the balance of the heat input between the center and the edges of the pattern changes as the temperature changes. Variations in the heating profile oftentimes cause “hotspots” within the oxygen sensing element, which result in thermal shock. In such a configuration, because the oxygen sensing element is usually fabricated from a ceramic material, differing rates of expansion often cause tensile stresses to be experienced along the interfaces of the hotter and colder areas. Such tensile stresses may, over time, cause the oxygen sensing elements to fracture and function improperly, thereby communicating inaccurate information for the control of the air/fuel ratio. In such an instance, the oxygen sensor will require replacement to ensure maximum efficiency of the system operation.
BRIEF SUMMARY
A heater pattern for a heater of a gas sensor in which a temperature profile is manipulated is described below. The heater pattern utilizes a thermistor element configured in such a manner so as to reduce the number of hotspots in the gas sensor. The heater includes a substrate and the thermistor element disposed thereon. The thermistor element is arranged so as to define an edge pattern extending about a perimeter of the substrate and a center pattern serially connected to the edge pattern. The center pattern extends over a portion of the substrate that is intermediate the perimeter of the substrate. In a preferred embodiment, the thermistor element is screen printed onto the substrate to a thickness of about 5 microns to about 50 microns, and preferably to a thickness of about 10 microns to about 40 microns. The edge and center patterns are furthermore preferably formed of materials having differing coefficients of thermal resistivity, e.g., platinum and platinum/palladium blends. A method of heating the gas sensor includes disposing the thermistor element in an electrically serial configuration about a perimeter of the substrate and over a portion of the substrate intermediate the perimeter of the substrate and pass an electric current through the thermistor element.
The above-described and other features and advantages of the present invention will be appreciated and understood by those skilled in the art from the following detailed description, drawings, and appended claims.


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