System and method for heat exchanger control based on real-time corrosion monitoring

What is claimed is: 1. A method of controlling corrosion of a heat exchange surface of a heat exchanger having a hot gas inlet, a hot gas outlet, a cold side fluid inlet and a cold side outlet, the method comprising: determining a temperature of a surface of the heat exchanger at a first location; controlling a temperature of a corrosion sensing system to a first temperature based on the temperature of the surface of the heat exchanger at the first location, the corrosion sensing system including a plurality of corrosion sensing devices, each corrosion sensing device having a corrosion sensor coupled to a temperature sensor, wherein controlling the temperature of the corrosion sensing system includes providing a temperature compensation device at the first location integrated with the corrosion sensing system, wherein the temperature compensation device includes a first tube with a closed end and an opposing open end housing the corrosion sensing system therein and a second tube disposed within the first tube, each of the plurality of corrosion sensing devices coupled to an inner wall of the first tube in a spaced arrangement, wherein the second tube is open at a first end and an opposing second end, the second tube configured to receive cooling air that flows therethrough towards the closed end of the first tube, the cooling air reflecting off the closed end of the first tube back towards the open end of the first tube, the reflected cooling air directly cooling each of the plurality of corrosion sensing devices while flowing towards the open end of the first tube, wherein the temperature compensation device controls the cooling of each of the plurality of corrosion sensing devices that form the corrosion sensing system as a function of an amount of the cooling air that is directed through the first tube and the second tube, wherein each of the plurality of corrosion sensing devices includes a microcontroller having a communications interface enabling communication with the other corrosion sensing devices that form the corrosion sensing system and a control unit operatively coupled to the plurality of corrosion sensing devices, a processing module, a sensor interface to communicate with a corresponding corrosion sensor and temperature sensor, and a power source to power the communications interface, the processing module, and the sensor interface, wherein the plurality of corrosion sensing devices are configured to communicate with each other, coordinate measurements and pass data relating to the coordinate measurements to the control unit; determining a corrosion rate associated with the heat exchange surface of the heat exchanger at the first location for the first temperature; comparing the corrosion rate to an expected corrosion rate associated with the first location and first temperature; determining a cold side fluid inlet temperature target for the heat exchanger based at least in part on the comparing the corrosion rate at the first location; and controlling a cold side fluid inlet temperature based at least in part on the fluid inlet temperature target, corrosion rate, and an expected corrosion rate. 2. The method as recited in claim 1 , wherein the controlling the temperature of the corrosion sensing system to the first temperature includes controlling the temperature of the corrosion sensing system to a current temperature of the heat exchanger. 3. The method as recited in claim 1 , wherein the determining of the corrosion rate associated with the heat exchange surface of the heat exchanger is based on measuring an electrical resistance at the first location. 4. The method as recited in claim 3 , wherein the electrical resistance at the first location is compared to a baseline electrical resistance measured under selected conditions. 5. The method as recited in claim 4 , wherein the selected conditions include the first location at the first temperature at an initial time. 6. The method as recited in claim 1 , wherein the controlling the cold side fluid inlet temperature is based on at least one of: controlling a flow rate of a heat exchange medium to the cold side inlet of the heat exchanger; and controlling a temperature of the heat exchange medium to the cold side inlet of the heat exchanger. 7. The method as recited in claim 1 , further comprising: controlling a temperature of the corrosion sensing system at the first location at the heat exchange surface of the heat exchanger to a second temperature; determining a second corrosion rate associated with the heat exchange surface of the heat exchanger at the second temperature; comparing the second corrosion rate to an expected corrosion rate associated with the second temperature; determining a second cold side inlet temperature target for the heat exchanger based at least in part on the comparing step and the second corrosion rate at the second temperature; and controlling the cold side inlet temperature based at least in part on the second cold side inlet temperature and second corrosion rate at the second temperature. 8. The method as recited in claim 7 , wherein the second temperature is selected based at least in part on an expected improved corrosion rate of the heat exchanger. 9. The method as recited in claim 1 , wherein the first location is based on likely corrosion locations of the heat exchange surfaces of the heat exchanger. 10. The method as recited in claim 9 , wherein the first location is selected to be in proximity to the hot gas outlet of the heat exchanger. 11. A system for monitoring corrosion of a heat exchange surface of a heat exchanger, the system comprising: a heat exchanger having a hot gas inlet, a hot gas outlet, a cold side inlet and a cold side outlet; a corrosion sensing system disposed at a first location at the heat exchange surface of the heat exchanger to measure a corrosion rate of the heat exchange surface for a first temperature, wherein the corrosion sensing system includes a plurality of corrosion sensing devices, each corrosion sensing device having a corrosion sensor coupled to a temperature sensor; a temperature compensation device integrated with the corrosion sensing system that is controllable and operable to control the temperature of the corrosion sensing system, wherein the temperature compensation device includes a first tube with a closed end and an opposing open end housing the corrosion sensing system device and a second tube disposed within the first tube, each of the plurality of corrosion sensing devices coupled to an inner wall of the first tube in a spaced arrangement, wherein the second tube is open at a first end and an opposing second end, the second tube configured to receive cooling air that flows therethrough towards the closed end of the first tube, the cooling air reflecting off the closed end of the first tube back towards the open end of the first tube, the reflected cooling air directly cooling each of the plurality of corrosion sensing devices while flowing towards the open end of the first tube, wherein the temperature compensation device controls the cooling of each of the plurality of corrosion sensing devices that form the corrosion sensing system as a function of an amount of the cooling air that is directed through the first tube and the second tube, wherein each of the plurality of corrosion sensing devices includes a microcontroller having a communications interface enabling communication with the other corrosion sensing devices that form the corrosion sensing system and a control unit operatively coupled to the plurality of corrosion sensing devices, a processing module, a sensor interface to communicate with a corresponding corrosion sensor and temper