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A temperature compensating fluid flow sensing system is provided that comprises a resistance-based sensor element that is included in a constant voltage anemometer circuit configured to establish and maintain a command voltage across the first sensor element and to provide a constant voltage anemome

A temperature compensating fluid flow sensing system is provided that comprises a resistance-based sensor element that is included in a constant voltage anemometer circuit configured to establish and maintain a command voltage across the first sensor element and to provide a constant voltage anemometer (CVA) output voltage corresponding to the resistance change in the first sensor element due to heat transfer between the first sensor element and the fluid. A controller is configured to establish the command voltage based on a desired overheat across the sensor and an actual overheat across the first sensor element. A power dissipation (PDR) module is configured to determine at least one fluid flow parameter and an actual overheat value based at least in part on the CVA output voltage and to transmit to the controller the actual overheat for use by the controller in updating the command voltage.

대표청구항 ▼

What is claimed is: 1. A temperature compensating fluid flow sensing system comprising: a first resistance-based sensor element positionable in a fluid flow stream, the first sensor element having a sensor resistance that varies with fluid flow conditions based on heat transfer between the first se

What is claimed is: 1. A temperature compensating fluid flow sensing system comprising: a first resistance-based sensor element positionable in a fluid flow stream, the first sensor element having a sensor resistance that varies with fluid flow conditions based on heat transfer between the first sensor element and the fluid; a first constant voltage anemometer circuit including the first sensor element, the first constant voltage anemometer circuit being configured to establish and maintain a command voltage across the first sensor element and to provide a CVA output voltage corresponding to the resistance change in the first sensor element due to heat transfer between the first sensor element and the fluid; a controller in communication with the first constant voltage anemometer circuit, the controller being configured to establish the command voltage based on a desired overheat across the sensor and an actual overheat across the first sensor element; and a PDR module in communication with the first constant voltage anemometer circuit and the controller, the PDR module being configured to receive the CVA output voltage and the command voltage from the first constant voltage anemometer circuit, to determine at least one fluid flow parameter and an actual overheat value based at least in part on the CVA output voltage from the first constant voltage anemometer, and to transmit to the controller the actual overheat for use by the controller in updating the command voltage. 2. A sensing system according to claim 1 wherein the controller is configured to receive the desired overheat via operator input. 3. A sensing system according to claim 1 wherein the PDR module is configured to calculate the actual sensor overheat based on the desired overheat, the command voltage, the output voltage and a cold resistance of the sensor element. 4. A sensing system according to claim 1 wherein at least one of the set consisting of the controller, the PDR module, and a combination of the controller and the PDR module is configured for determining a cold resistance of the sensor element. 5. A sensing system according to claim 1 further comprising: a second resistance-based sensor element positionable in a fluid flow stream, the second sensor element having a sensor resistance that varies with fluid flow conditions based on heat transfer between the second sensor element and the fluid; and a second constant voltage anemometer circuit including the second sensor element, the second constant voltage anemometer circuit being configured to establish and maintain a command voltage across the second sensor element and to provide a CVA output voltage corresponding to the resistance change in the second sensor element due to heat transfer between the second sensor element and the fluid, wherein the controller is in communication with the second constant voltage anemometer circuit to provide the command voltage thereto, the controller being configured to establish the command voltage based on the desired overheat, the actual overheat across the first sensor element and an actual overheat across the second sensor element, and wherein the PDR module is in communication with the second constant voltage anemometer circuit and is configured to receive the CVA output voltage and the command voltage from the second constant voltage anemometer circuit, to use the CVA output voltage of the second constant voltage anemometer with the output of the first constant voltage anemometer to determine the at least one fluid flow parameter and the actual overheat value, and to calculate and transmit to the controller the actual overheat for use by the controller in updating the command voltage. 6. A sensing system according to claim 1 wherein the resistance-based sensor element is a thin film sensor appliable to a surface of an object that is immersable in the fluid flow stream. 7. A sensing system according to claim 6 wherein the fluid flow parameter is a shear stress at the object surface. 8. A method of determining a fluid flow parameter using a first resistance-based sensor element in a first constant voltage anemometer circuit, the first resistance-based sensor element being immersible in a fluid stream, the method comprising: selecting a desired sensor overheat for the first resistance-based sensor element; determining a zero-flow power dissipated value for the first sensor element for the desired sensor overheat; determining a flow power dissipated value for the first sensor element under a set of flow conditions for the desired sensor overheat; and calculating the fluid parameter at least in part based on the flow and zero-flow power dissipation values for the first sensor element. 9. A method according to claim 8 wherein the first resistance-based sensor element is a thin film sensor applied to a surface immersible in the fluid stream and the fluid flow parameter is a fluid shear stress at the surface. 10. A method according to claim 8 wherein the first resistance-based sensor element is a hot wire anemometer element. 11. A method according to claim 8 wherein: the action of determining a zero-flow power dissipated value comprises selecting a plurality of voltages to be applied to the first sensor element, the plurality of voltages defining a voltage range having an associated sensor overheat range, the voltages being selected to provide a sensor overheat range encompassing the desired sensor overheat; for each of the plurality of voltages, establishing and maintaining the voltage across the first sensor element using the constant voltage anemometer circuit under no-flow conditions and determining an associated power dissipated value for the applied voltage; and determining the zero-flow power dissipated value for the desired sensor overheat by interpolation using the sensor overheat values and the zero-flow power dissipated values associated with the plurality of voltages, and the action of determining a flow power dissipated value comprises for each of the plurality of voltages, establishing and maintaining the voltage across the first sensor element using the constant voltage anemometer circuit under the set of flow conditions and determining an associated power dissipated value for the applied voltage; and determining the flow power dissipated value for the desired sensor overheat by interpolation using the sensor overheat values and the flow power dissipated values associated with the plurality of voltages. 12. A method according to claim 8 wherein: the action of determining a zero-flow power dissipated value comprises establishing and maintaining the desired sensor overheat across the first sensor element using the first constant voltage anemometer circuit under zero-flow conditions, and the action of determining a flow power dissipated value comprises establishing and maintaining the desired sensor overheat across the first sensor element using the first constant voltage anemometer circuit under the set of flow conditions. 13. A method according to claim 12 wherein: the action of determining a zero-flow power dissipated value further comprises determining a zero-flow cold resistance value for the first sensor element; and calculating a required hot sensor resistance for the first sensor element for the desired sensor overheat, and the action of determining a flow power dissipated value further comprises determining a flow cold resistance value for the first sensor element under the set of flow conditions; and calculating a required hot sensor resistance for the first sensor element for the desired sensor overheat under the set of flow conditions. 14. A method according to claim 8 further comprising: providing a second resistance-based sensor element in a constant voltage anemometer circuit, the second resistance-based sensor element being immersible in the fluid stream; determining a zero-flow power dissipated value for the second sensor element for the desired sensor overheat; and determining a flow power dissipated value for the second sensor element under the set of flow conditions for the desired sensor overheat, wherein the fluid parameter is calculated based on the flow and zero-flow power dissipation values for both the first sensor element and the second sensor element. 15. A method according to claim 14 wherein: the action of determining a zero-flow power dissipated value for the first sensor element comprises: selecting a first plurality of voltages to be applied to the first sensor element, the plurality of voltages defining a voltage range having an associated sensor overheat range, the voltages being selected to provide a sensor overheat range encompassing the desired sensor overheat; for each of the plurality of voltages, establishing and maintaining the voltage across the first sensor element using the constant voltage anemometer circuit under no-flow conditions and determining an associated power dissipated value for the applied voltage; and determining the zero-flow power dissipated value for the desired sensor overheat by interpolation using the sensor overheat values and the zero-flow power dissipated values associated with the plurality of voltages, the action of determining a zero-flow power dissipated value for the second sensor element comprises: selecting a second plurality of voltages to be applied to the second sensor element, the plurality of voltages defining a voltage range having an associated sensor overheat range, the voltages being selected to provide a sensor overheat range encompassing the desired sensor overheat; for each of the plurality of voltages, establishing and maintaining the voltage across the second sensor element using the constant voltage anemometer circuit under no-flow conditions and determining an associated power dissipated value for the applied voltage; and determining the zero-flow power dissipated value for the desired sensor overheat by interpolation using the sensor overheat values and the zero-flow power dissipated values associated with the plurality of voltages, the action of determining a flow power dissipated value for the first sensor element comprises for each of the plurality of voltages, establishing and maintaining the voltage across the first sensor element using the constant voltage anemometer circuit under the set of flow conditions and determining an associated power dissipated value for the applied voltage; and determining the flow power dissipated value for the first sensor for the desired sensor overheat by interpolation using the sensor overheat values and the flow power dissipated values associated with the plurality of voltages, and the action of determining a flow power dissipated value for the second sensor element comprises for each of the plurality of voltages, establishing and maintaining the voltage across the second sensor element using the constant voltage anemometer circuit under the set of flow conditions and determining an associated power dissipated value for the applied voltage; and determining the flow power dissipated value for the second sensor for the desired sensor overheat by interpolation using the sensor overheat values and the flow power dissipated values associated with the plurality of voltages. 16. A method according to claim 14 wherein: the action of determining a zero-flow power dissipated value for the first sensor element comprises establishing and maintaining the desired sensor overheat across the first sensor element using the first constant voltage anemometer circuit under zero-flow conditions, the action of determining a zero-flow power dissipated value for the second sensor element comprises establishing and maintaining the desired sensor overheat across the second sensor element using the second constant voltage anemometer circuit under zero-flow conditions, the action of determining a flow power dissipated value for the first sensor element comprises establishing and maintaining the desired sensor overheat across the first sensor element using the first constant voltage anemometer circuit under the set of flow conditions, and the action of determining a flow power dissipated value for the second sensor element comprises establishing and maintaining the desired sensor overheat across the second sensor element using the second constant voltage anemometer circuit under the set of flow conditions. 17. A method according to claim 16 wherein: the action of determining a zero-flow power dissipated value for the first sensor element further comprises determining a zero-flow cold resistance value for the first sensor element; and calculating a required hot sensor resistance for the first sensor element for the desired sensor overheat, the action of determining a zero-flow power dissipated value for the second sensor element further comprises determining a zero-flow cold resistance value for the second sensor element; and calculating a required hot sensor resistance for the second sensor element for the desired sensor overheat, the action of determining a zero-flow power dissipated value for the first sensor element further comprises determining a zero-flow cold resistance value for the first sensor element; and calculating a required hot sensor resistance for the first sensor element for the desired sensor overheat, the action of determining a zero-flow power dissipated value for the second sensor element further comprises determining a zero-flow cold resistance value for the second sensor element; and calculating a required hot sensor resistance for the second sensor element for the desired sensor overheat, and wherein the action of determining a flow power dissipated value further comprises determining a flow cold resistance value for the first sensor element under the set of flow conditions; and calculating a required hot sensor resistance for the first sensor element for the desired sensor overheat under the set of flow conditions. 18. A method of determining a fluid flow parameter using a plurality of resistance-based sensor elements each being included in an associated constant voltage anemometer circuit and being immersible in a fluid stream, the method comprising: selecting a desired sensor overheat for the resistance-based sensor elements; determining a zero-flow power dissipated value for each sensor element for the desired sensor overheat; determining a flow power dissipated value for each sensor element under a set of flow conditions for the desired sensor overheat; and calculating the fluid parameter based on the flow and zero-flow power dissipation values for sensor elements.