Fluid flow monitoring system

What is claimed is: 1. A system to monitor fluids in nozzles, the system comprising: a spray nozzle configured to release a fluid according to a desired flow rate; a thermal material positioned in a flow path of the fluid inside the spray nozzle in fluid communication with an inlet integrally formed as part of a circular mount of the spray nozzle, wherein the thermal material is entirely enclosed within a body of the spray nozzle, and is sized and dimensioned to conform to an interior surface of an orifice coaxially aligned with the inlet; an electronic feedback circuit designed to attempt to maintain at least one of a current through the thermal material and a voltage across the thermal material; wherein a measured value of at least one of the current and the voltage different from a target value indicates a change in resistance of the thermal material, and wherein a degree of a plugged condition or a type of fluid flow restriction is determined based on the measured change in resistance; wherein a range of the measured value is correlated with an actual flow rate of the fluid, and wherein the range of the measured value is dynamically adjusted as the flow rate increases or decreases to maintain at least one of the current through the thermal material or the voltage across the thermal material by adjusting a baseline signal based on a computed average of the current; and a digital processor circuit designed to generate an output signal to initiate a corrective action to disable current flow through the thermal material if the actual flow rate falls below a predetermined threshold to allow for a temperature of the thermal material to decrease, and wherein a reset command is generated by the digital processor circuit to reenable current flow through the thermal material when the temperature reaches a lower temperature threshold. 2. The system of claim 1 , wherein the electronic feedback circuit is electronically connected to leads of the thermal material, and at least part of the electronic feedback circuit is outside of the flow path but still inside the spray nozzle. 3. The system of claim 1 , wherein the electronic feedback circuit is in communication with a computer having a screen that displays an alert of the spray nozzle, as determined by a deviation of the measured value past a pre-set threshold. 4. The system of claim 1 , wherein the electronic feedback circuit includes a pulse width modulated circuit, and wherein a pulse width is adjusted to maintain the current through the thermal material. 5. The system of claim 1 , wherein the thermal material comprises at least one of a thermistor and a resistor. 6. The system of claim 5 , wherein a sense resistor is in series with the thermal material, and the voltage across the sense resistor indicates the current through the thermal material. 7. The system of claim 5 , wherein the current or the voltage past a threshold value is flagged as a stagnant state of the spray nozzle and an alert is issued. 8. The system of claim 5 , wherein the spray nozzle includes multiple thermal materials, each of which is associated with a fluid outlet of the spray nozzle. 9. The system of claim 1 , wherein a plurality of the spray nozzle is mounted on a spray boom for an agricultural application, and wherein each of the plurality of spray nozzles includes the thermal material to provide flow values; and a deviation among the flow values indicate anomalous fluid flow in at least one of the plurality of spray nozzles associated with the deviation. 10. An agricultural spray system comprising: a spray boom mounted on a motor vehicle; a fluid distribution pipe mounted to the spray boom; spray nozzles mounted along the fluid distribution pipe to receive a fluid; each of the spray nozzles include a thermal sensor system having: a thermal sensor positioned in a fluid flow path inside each of the spray nozzles in fluid communication with an inlet integrally formed as part of a circular mount of the spray nozzle, wherein the thermal sensor is entirely enclosed within a body of the spray nozzle, and is sized and dimensioned to conform to an interior surface of an orifice coaxially aligned with the inlet; an electronic circuit that attempts to maintain at least one of a current through the thermal sensor and a voltage across the thermal sensor; wherein a measured value of at least one of the current and the voltage different from a target value indicates a change in resistance of the thermal sensor, and wherein a degree of a plugged condition or a type of fluid flow restriction is determined based on the measured change in resistance; wherein the measured value correlates with a flow rate of the fluid in each of the spray nozzles, and wherein a range of the measured value is dynamically adjusted as the flow rate increases or decreases to maintain at least one of the current through the thermal sensor or the voltage across the thermal sensor by adjusting a baseline signal based on a computed average of the current; a digital processor circuit designed to generate an output signal to initiate a corrective action to disable current flow through the thermal sensor if the flow rate falls below a predetermined threshold to allow for a temperature of the thermal sensor to decrease, and wherein a reset command is generated by the digital processor circuit to reenable current flow through the thermal sensor when the temperature reaches a lower temperature threshold. 11. The agricultural spray system of claim 10 , wherein the electronic circuit is electronically connected to leads of the thermal sensor, and at least part of the electronic circuit is outside of the fluid flow path but still inside each of the spray nozzles; and wherein the electronic circuit includes a pulse width modulated circuit, and wherein a pulse width is adjusted to maintain the current through the thermal sensor. 12. The agricultural spray system of claim 10 , wherein the measured value from each of the spray nozzles is compared with a maximum and a minimum threshold value. 13. The agricultural spray system of claim 10 , wherein initiating the corrective action further comprises initiating a corrective action to expel a stagnant state, wherein the current or the voltage past a threshold value is flagged as the stagnant state of the spray nozzle; and where under the stagnant state, an alert is issued. 14. The agricultural spray system of claim 13 , wherein the corrective action includes at least changing a position of the spray boom, changing a position of the spray nozzle, or plunging a valve inside the spray nozzle associated with the stagnant state. 15. The agricultural spray system of claim 10 , wherein the thermal sensor comprises at least one of a thermistor or a resistor. 16. The agricultural spray system of claim 13 , wherein each of the spray nozzles includes a first flow valve and a second flow valve; the thermal sensor is located between the first flow valve and a first spray nozzle outlet; and a second thermal sensor is located between the second flow valve and a second spray nozzle outlet. 17. The agricultural spray system of claim 10 , wherein the spray boom comprises composite fiber material. 18. The agricultural spray system of claim 10 , wherein the fluid distribution pipe comprises a fluid section valve; and the fluid section valve also includes the thermal sensor to detect a section flow rate through the section valve. 19. An agricultural spray system comprising: a spray boom mounted on a motor vehicle; a fluid distribution pip