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Apparatus and methods are disclosed to measure airflow within a chassis-cooling pathway of an appliance. The rate of airflow is determined based on the differential heating among a pair of sensor devices, such as thermistors, transistors, diodes or resistive thermal devices operating at distinctly d

Apparatus and methods are disclosed to measure airflow within a chassis-cooling pathway of an appliance. The rate of airflow is determined based on the differential heating among a pair of sensor devices, such as thermistors, transistors, diodes or resistive thermal devices operating at distinctly different power levels. The appliance utilizes the calculated airflow rate to perform safety-related tasks, such as de-energizing heating elements when low or no airflow is detected.

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1. An appliance comprising: an oven chassis;at least one cooling air blower;a cooling air passageway for circulating cooling air from the at least one cooling air blower within and/or around at least a part of the oven chassis;an air flow measuring device for determining the rate of air flowing thro

1. An appliance comprising: an oven chassis;at least one cooling air blower;a cooling air passageway for circulating cooling air from the at least one cooling air blower within and/or around at least a part of the oven chassis;an air flow measuring device for determining the rate of air flowing through the cooling air passageway and is immersed within an air flow stream of the cooling air passageway and which includes a first sensing device supplied with a current flowing therethrough and causing the first sensing device to dissipate a power such that the first sensing device exhibits a significant self-heating effect, the significant self-heating effect of the first sensing device being dependent on the rate of air flowing through the cooling air passageway, and a second sensing device supplied with a current flowing therethrough and causing the second sensing device to dissipate a power such that the second sensing device that exhibits a significantly smaller self-heating effect than the first sensing device due to an amount of current that flows through the second sensing device; anda controller that monitors temperature dependent electrical characteristics of the first sensing device and the second sensing device, and utilizes differences in temperatures or temperature-dependent electrical characteristics between the first sensing device and the second sensing device of the airflow measuring device to calculate airflow within the cooling air passageway. 2. The appliance of claim 1, wherein the first sensing device and the second sensing device are thermally isolated from each other and both sensing devices are in thermal contact with the airflow being measured. 3. The appliance of claim 1, wherein the first sensing device and second sensing device are both electronic devices and in which the first sensing device dissipates a higher power than the second sensing device to produce a greater temperature differential between the first and second sensing devices when substantially no air flow occurs thereover than when a substantial amount of air flows thereover. 4. The appliance of claim 1, wherein the first sensing device and the second sensing device exchange operational roles periodically with one another wherein the first sensing device is operated at lower power having the significantly smaller self-heating effect and the second sensing device is operated at higher power having significant self-heating to provide substantially uniform wearing of the devices during product operation. 5. The appliance of claim 1, further comprising: a heat sourcewherein the controller interprets the temperature-dependent electrical characteristics of the two sensing devices within the air flow measuring device to determine air flow rate within the air flow passageway and de-energizes the heat source when the calculated air flow rate is below a prescribed threshold and allows activation of the heat source when the calculated air flow rate is above a prescribed threshold. 6. The appliance of claim 1, wherein the controller powers the first sensing device at a substantially greater duty cycle than the second sensing device that causes the first sensing device to dissipate substantially more power than the second sensing device so that a greater temperature differential exists when less air is flowing thereover than when more air is flowing thereover. 7. The appliance of claim 1, wherein the first and second sensing devices are arranged in a Wheatstone bridge circuit configuration that creates two measurement nodes, the voltage difference between these nodes changing according to the temperature difference between the first and second sensing devices, and in which this voltage difference is used by the controller to determine the air flow rate within the air passageway. 8. The appliance of claim 7, wherein the first and second sensing devices arranged in a Wheatstone bridge circuit configuration are any of a thermistor, a resistance temperature device (RTD), a thermocouple, a diode, a diode-connected transistor, or any of the aforementioned devices thermally bonded to a heat-dissipating device. 9. The appliance of claim 7, wherein the first sensing device exhibits a substantially lower impedance than the second sensing device thereby causing the first sensing device to dissipate substantially more power than the second sensing device so that a greater temperature differential exists between the first and second sensing devices when less air is flowing thereover than when more air is flowing thereover, and wherein the controller determines a difference in temperature-dependent voltages and/or a difference in temperature between the two sensing devices with an analog means having an operational amplifier, instrumentation amplifier, or comparator, or with a digital means having a microprocessor with analog/digital ports to sample the two voltages and calculate the voltage differences. 10. The appliance of claim 7, wherein the first sensing device is supplied with a substantially greater current and/or voltage than the second sensing device thereby causing the first sensing device to dissipate substantially more power than the second sensing device so that a greater temperature differential exists between the first and second sensing devices when less air is flowing thereover than when more air is flowing thereover. 11. The appliance of claim 7, wherein the first sensing device is operated at a substantially greater duty cycle than the second sensing device thereby causing the first sensing device to dissipate substantially more power than the second sensing device so that a greater temperature differential exists between the first and second sensing devices when less air is flowing thereover than when more air is flowing thereover. 12. The appliance of claim 1, wherein the first and second sensing devices are either a diode or a diode-connected transistor which are both operated periodically at two or more low current levels to measure the devices temperatures without causing significant self-heating of the devices, and in which the first sensing device is also periodically operated at a substantially larger current level so that significant self-heating occurs when temperature measurements are not being taken, and in which the temperature difference between the sensing devices is calculated and used by the controller to determine the rate of air flow within the air passageway. 13. The appliance of claim 12, wherein the first and second sensing devices are operated periodically at two or more substantially differing low current levels by means of one or more constant current source driver circuits whose output current level is controlled by the controller, and in which the voltages of both sensing devices is measured by the controller while operating at each of the commanded current levels. 14. The appliance of claim 12, wherein the first sensing device is operated periodically at a current level which is sufficiently large to cause self-heating of the first sensing device. 15. The appliance of claim 12, wherein the sensing device temperatures are calculated by the controller using the device voltages measured at two or more low current levels using the well-known “Brokaw Bandgap” equation, and in which the difference in calculated temperatures between the first and second sensing devices is used by the controller as an indication of the air flow rate within the air passageway. 16. The appliance of claim 1 wherein the air flow measuring device is disposed in an oven operating environment having a temperature range of about 200 degrees F. to about 500 degrees F.