Method to detect tube leakage in shell and tube thermosiphon reboilers

What is claimed is: 1. An automated method of detecting tube leakage in a shell and tube thermosiphon reboiler used to drive a fractionating column, the method comprising: controlling, by a control circuit using process data, a fractionating process in the fractionating column using the shell and tube thermosiphon reboiler, the process data comprising: a flow rate of feedstock input to the column, as monitored by a feedstock input flow rate monitor; a position of a feedstock input valve for controlling the feedstock input flow rate, as monitored by a feedstock input valve position monitor; a position of a heating fluid input valve for controlling a flow rate of heating fluid input to a tube side of the reboiler, as monitored by a heating fluid input valve position monitor, a flow rate of the heating fluid output from the tube side of the reboiler, as monitored by a heating fluid output flow rate monitor; a temperature of bottoms fluid input to a shell side of the reboiler, as monitored by a bottoms fluid input temperature monitor; and a temperature of the bottoms fluid output from the shell side of the reboiler, as monitored by a bottoms fluid output temperature monitor; continuously receiving, by the control circuit, the monitored feedstock input valve position and feedstock input flow rate; continuously determining, by the control circuit using the received feedstock input valve position and feedstock input flow rate, that the column is in service or not in service; continuously receiving, by the control circuit, the monitored heating fluid input valve position and heating fluid output flow rate; continuously determining, by the control circuit using the received heating fluid input valve position, that the shell and tube thermosiphon reboiler is inactive or active; continuously determining, by the control circuit using the received heating fluid output flow rate, that the reboiler is losing or not losing the heating fluid; continuously receiving, by the control circuit, the monitored bottoms fluid input temperature and bottoms fluid output temperature; continuously determining, by the control circuit using the received bottoms fluid input temperature and bottoms fluid output temperature, that the reboiler is heat exchanging or not heat exchanging; continuously determining, by the control circuit, that the tube leakage in the reboiler is taking place when the column is determined to be in service, the reboiler is determined to be inactive, the reboiler is determined to be losing the heating fluid, and the reboiler is determined to be heat exchanging, and is not taking place otherwise; and generating an alert, by the control circuit, when the tube leakage in the reboiler is determined to be taking place. 2. The method of claim 1 , wherein: continuously determining that the column is in service comprises determining when both the received feedstock input valve position exceeds a first threshold and the received feedstock input flow rate exceeds a second threshold, and is not in service otherwise. 3. The method of claim 1 , wherein: continuously receiving the heating fluid input valve position comprises setting a first start time to the current time at a beginning of the continuous receiving of the heating fluid input valve position and when the received heating fluid input valve position exceeds a third threshold; and continuously determining that the reboiler is inactive comprises determining when the difference between the current time and the first start time is at least a fourth threshold, and is active otherwise. 4. The method of claim 1 , wherein: continuously receiving the heating fluid output flow rate comprises setting a second start time to the present current time at a beginning of the continuous receiving of the heating fluid output flow rate and when the received heating fluid output flow rate exceeds a fifth threshold; and continuously determining that the reboiler is losing the heating fluid comprises determining when the difference between the current time and the second start time is at least a sixth threshold, and is not losing the heating fluid otherwise. 5. The method of claim 1 , wherein: continuously determining that the reboiler is heat exchanging comprises determining when the difference between the received bottoms fluid output temperature and the received bottoms fluid input temperature is at least a seventh threshold, and is not heat exchanging otherwise. 6. The method of claim 1 , further comprising shutting down, by the control circuit, the reboiler when the tube leakage in the reboiler is determined to be taking place. 7. The method of claim 1 , wherein the feedstock is petroleum, the column is a crude oil stabilizer, and the heating fluid is steam or water. 8. A control circuit to detect tube leakage in a shell and tube thermosiphon reboiler used to drive a fractionating column, the control circuit comprising: logic to control a fractionating process using process data, the fractionating process taking place in the fractionating column using the shell and tube thermosiphon reboiler, the process data comprising: a flow rate of feedstock input to the column, as monitored by a feedstock input flow rate monitor; a position of a feedstock input valve for controlling the feedstock input flow rate, as monitored by a feedstock input valve position monitor; a position of a heating fluid input valve for controlling a flow rate of heating fluid input to a tube side of the reboiler, as monitored by a heating fluid input valve position monitor, a flow rate of the heating fluid output from the tube side of the reboiler, as monitored by a heating fluid output flow rate monitor; a temperature of bottoms fluid input to a shell side of the reboiler, as monitored by a bottoms fluid input temperature monitor; and a temperature of the bottoms fluid output from the shell side of the reboiler, as monitored by a bottoms fluid output temperature monitor; logic to continuously receive the monitored feedstock input valve position and feedstock input flow rate; logic to continuously determine, using the received feedstock input valve position and feedstock input flow rate, that the column is in service or not in service; logic to continuously receive the monitored heating fluid input valve position and heating fluid output flow rate; logic to continuously determine, using the received heating fluid input valve position, that the shell and tube thermosiphon reboiler is inactive or active; logic to continuously determine, using the received heating fluid output flow rate, that the reboiler is losing or not losing the heating fluid; logic to continuously receive the monitored bottoms fluid input temperature and bottoms fluid output temperature; logic to continuously determine, using the received bottoms fluid input temperature and bottoms fluid output temperature, that the reboiler is heat exchanging or not heat exchanging; logic to continuously determine that the tube leakage in the reboiler is taking place when the column is determined to be in service, the reboiler is determined to be inactive, the reboiler is determined to be losing the heating fluid, and the reboiler is determined to be heat exchanging, and is not taking place otherwise; and logic to generate an alert when the tube leakage in the reboiler is determined to be taking place. 9. The control circuit of claim 8 , wherein: the logic to continuously determine that the column is in service comprises logic to determine that the column is in service when both the received feedstock input valve position exceeds a first threshold and the received feedstock input flow rate exceeds a second threshold, and is not in service otherwis