Control process for liquid organic hydrogen carrier process

What is claimed is: 1 . A process for controlling a liquid organic hydrogen carrier (LOHC) process comprising: measuring a pressure of a separator; controlling a hydrogenation reactor using a first pressure controller and a first differential temperature controller based on the measured pressure of the separator; measuring an inlet temperature or an outlet temperature or both of the hydrogenation reactor; controlling the inlet temperature of the hydrogenation reactor using a first inlet temperature controller and a heat source or a cooling source based on the measured inlet temperature; controlling a flow rate of hydrogen to the hydrogenation reactor using a hydrogen flow controller and a second pressure controller limiting a flow rate of a source of hydrogen; and controlling a differential temperature of the hydrogenation reactor using a toluene flow controller and the measured inlet temperature and the measured outlet temperature of the hydrogenation reactor. 2 . The process of claim 1 further comprising: selecting a predetermined maximum temperature and a predetermined minimum temperature for the hydrogenation reactor; and overriding the first inlet temperature controller if the measured temperature is greater than the predetermined maximum temperature or if the measured temperature is less than the predetermined minimum temperature. 3 . The process of claim 1 further comprising: selecting a predetermined maximum temperature rate of change and a predetermined minimum temperature rate of change for the hydrogenation reactor; determining a temperature rate of change for the hydrogenation reactor; and overriding the first inlet temperature controller if the determined temperature rate of change is greater than the predetermined maximum temperature rate of change or if the determined temperature rate of change is less than the predetermined minimum temperature rate of change. 4 . The process of claim 1 wherein controlling the differential temperature of the hydrogenation reactor comprises controlling a toluene flow rate into the hydrogenation reactor based on a difference between the measured inlet temperature and the measured outlet temperature. 5 . The process of claim 1 further comprising: selecting a predetermined maximum temperature differential and a predetermined minimum temperature differential between the inlet temperature and the outlet temperature of the hydrogenation reactor; determining a temperature differential between the measured inlet temperature and the measured outlet temperature of the hydrogenation reactor; and overriding the first differential temperature controller if the temperature differential is greater than the predetermined maximum temperature differential or the temperature differential is less than the predetermined minimum temperature differential. 6 . The process of claim 1 further comprising: selecting a predetermined maximum pressure and a predetermined minimum pressure for the separator; and overriding the first pressure controller or the second pressure controller or both if the measured pressure is greater than the predetermined maximum pressure or if the measured pressure is less than the predetermined minimum pressure. 7 . The process of claim 1 further comprising: controlling a recycle stream from the separator to the hydrogenation reactor using a level controller on the separator and a recycle flow controller. 8 . The process of claim 1 further comprising: controlling a recycle stream from the separator to the hydrogenation reactor and a product stream using a level controller on the separator, a recycle flow controller, and a product flow controller. 9 . The process of claim 1 wherein the heat source comprises a steam heater, fired heater, hot oil heater, electric heater, or combinations thereof, and wherein the cooling source comprises a heat exchanger with a process stream having a lower temperature than the measured temperature. 10 . The process of claim 1 further comprising: controlling a temperature of a second hydrogenation reactor using the first pressure controller and a second differential temperature controller based on the measured pressure of the separator; measuring an inlet temperature or an outlet temperature or both of the second hydrogenation reactor; controlling the inlet temperature of the second hydrogenation reactor using a second inlet temperature controller and a second cooling source based on the measured temperature; and controlling a differential temperature of the second hydrogenation reactor using a second toluene flow controller and the measured inlet temperature and the measured outlet temperature of the second hydrogenation reactor. 11 . The process of claim 10 wherein the second cooling source comprises a steam generator, a heat exchanger, fired heater, hot oil heater, electric heater, or combinations thereof. 12 . A process for controlling a liquid organic hydrogen carrier (LOHC) process comprising: measuring a pressure of a separator; controlling a hydrogenation reactor using a first pressure controller and a first differential temperature controller based on the measured pressure of the separator; measuring an inlet temperature or an outlet temperature or both of the hydrogenation reactor; controlling an inlet temperature of the hydrogenation reactor using a first inlet temperature controller and a heat source or a cooling source based on the measured inlet temperature; controlling a flow rate of hydrogen to the hydrogenation reactor using a hydrogen flow controller and a second pressure controller limiting a flow rate of a source of hydrogen; controlling differential temperature of the hydrogenation reactor using a toluene flow controller and the measured inlet temperature and the measured outlet temperature of the hydrogenation reactor; controlling an inlet temperature of a second hydrogenation reactor using the first pressure controller and a second differential temperature controller based on the measured pressure of the separator; measuring an inlet temperature or an outlet temperature or both of the second hydrogenation reactor; controlling the inlet temperature of the second hydrogenation reactor using a second inlet temperature controller and a second cooling source based on the measured temperature; controlling a differential temperature of the second hydrogenation reactor using a second toluene flow controller and the measured inlet temperature and the measured outlet temperature of the second hydrogenation reactor. 13 . The process of claim 12 further comprising: selecting a predetermined maximum temperature and a predetermined minimum temperature for the hydrogenation reactor; and overriding the first inlet temperature controller if the measured temperature is greater than the predetermined maximum temperature or if the measured temperature is less than the predetermined minimum temperature. 14 . The process of claim 12 further comprising: selecting a predetermined maximum temperature rate of change and a predetermined minimum temperature rate of change for the hydrogenation reactor; determining a temperature rate of change for the hydrogenation reactor; and overriding the first inlet temperature controller if the determined temperature rate of change is greater than the predetermined maximum temperature rate of change or if the determined temperature rate of change is less than the predetermined minimum temperature rate of change. 15 . The process of claim 12 : wherein controlling the differential temperature of the hydrogenation