Estimation of unknown states for an electric water heater with thermal stratification and use of same in demand response and condition-based maintenance

1 . A water heater control system for controlling a water heater including a vertically oriented cylindrical water storage tank having a cylindrical wall, at least one heating element arranged to heat water in the water storage tank, and at least one temperature sensor arranged to measure water temperature in the water storage tank, the electric water heater control system comprising: a load controller comprising an electronic data processing device configured to operate the water heater including operating the at least one heating element based on temperature readings provided by the at least one temperature sensor to control water temperature of water in the water storage tank; and a water heater modeling component comprising an electronic data processing device configured to model the water heater using a one-dimensional model that includes: a vertical stack of disks representing the water volume in the cylindrical water storage tank, and a stack of annular segments surrounding the vertical stack of disks wherein the stack of annular segments represents the cylindrical wall of the cylindrical water storage tank. 2 . The water heater control system of claim 1 further comprising: a condition-based maintenance system comprising an electronic data processing device configured to detect a failure mode present in the water heater based on an output of the water heating model component. 3 . The water heater control system of claim 2 wherein the condition-based maintenance system is configured to detect a failure mode comprising insulation disturbance present in the water heater based on R-values or thermal conductivity values computed for the annular segments representing the cylindrical wall of the cylindrical water storage tank. 4 . The water heater control system of claim 2 wherein the condition-based maintenance system is configured to detect a failure mode comprising a heating element failure present in the water heater based on an increase over time of the thermal or volumetric capacity of the water in the water storage tank determined using the water heater modeling component. 5 . The water heater control system of claim 2 wherein the water heater is an electric water heater, the at least one heating element is a resistive heating element, and the condition-based maintenance system is configured to detect a failure mode comprising a heating element failure present in the water heater based on an increase in electrical resistance measured for the heating element over time 6 . The water heater control system of claim 2 wherein the condition-based maintenance system is configured to detect a failure mode comprising sediment buildup present in the water storage tank of the water heater based on a decrease over time of the thermal or volumetric capacity of the water in the water storage tank determined using the water heater modeling component. 7 . The water heater control system of claim 2 wherein the condition-based maintenance system is configured to detect a failure mode comprising a drip tube rupture present in the water heater based on more rapid cooling of the upper elevation disks of the vertical stacked disks as compared with the lower elevation disks during a hot water draw event. 8 . The water heater control system of claim 2 wherein the load controller is further configured to (i) communicate with an aggregation demand response dispatch engine comprising an electronic data processing device that is configured to send demand response commands to an aggregation of loads including the water heater and (ii) operate the water heater in accord with demand response commands received from the aggregation demand response dispatch engine. 9 . The water heater control system of claim 1 wherein the load controller is further configured to (i) communicate with an aggregation demand response dispatch engine comprising an electronic data processing device that is configured to send demand response commands to an aggregation of loads including the water heater and (ii) operate the water heater in accord with demand response commands received from the aggregation demand response dispatch engine, wherein a demand response operation performed by the cooperating load controller and aggregation demand response dispatch engine is based at least in part on energy stored in the vertically oriented cylindrical water storage tank as determined using the water heater modeling component. 10 . The water heater control system of claim 1 wherein the one-dimensional model comprises coupled differential equations including: for each disk of the vertical stack of disks representing the water volume in the cylindrical water storage tank, a differential equation expressing the time derivative of the temperature of the disk estimated by the one-dimensional model; and for each annular segment of the stack of annular segments representing the cylindrical wall of the cylindrical water storage tank, a differential equation expressing the time derivative of the temperature of the annular segment estimated by the one-dimensional model. 11 . The water heater control system of claim 1 wherein the load controller and the water heater modeling component are constructed as a single electronic data processing device configured to both operate the water heater and model the water heater using the one-dimensional model. 12 . A system comprising: a water heater including a water storage tank, at least one heating element arranged to heat water in the water storage tank, and at least one temperature sensor arranged to measure water temperature in the water storage tank; a load controller comprising an electronic data processing device configured to operate the water heater including operating the at least one heating element based on temperature readings provided by the at least one temperature sensor to control water temperature of water in the water storage tank; an aggregation demand response dispatch engine comprising an electronic data processing device configured to send demand response commands to load controllers of an aggregation of loads including the load controller configured to operate the water heater wherein the load controller is further configured to operate the water heater in accord with demand response commands received from the aggregation demand response dispatch engine; and a condition-based maintenance system comprising an electronic data processing device configured to detect a failure mode present in the water heater based on information including the temperature readings provided by the at least one temperature sensor and power input to the water heater. 13 . The system of claim 12 further comprising: a water heater modeling component comprising an electronic data processing device configured to model the water heater using a one-dimensional model of the water heater that receives as inputs the temperature readings provided by the at least one temperature sensor and power input to the water heater, wherein the condition-based maintenance system is configured to detect a failure mode present in the water heater based on parameter values estimated by the water heater modeling component. 14 . The system of claim 13 wherein the one-dimensional model includes: a vertical stack of disks representing water inside the water storage tank, and a vertical stack of annular segments that surrounds the vertical stack of disks and that represents the wall of the water storage tank. 15 . The system of claim 14 wherein the condition-based maintenance system is configured to detect a failure mode comprising insulatio