Dewatering a hydrocarbon storage tank

That which is claimed is: 1. A method of dewatering a hydrocarbon storage tank carrying a first fluid layer comprising a first hydrogen concentration and a second fluid layer comprising a second hydrogen concentration different than the first hydrogen concentration, the first fluid layer separated from the second fluid layer by an interface layer, the first fluid layer disposed between the interface layer and a base of the storage tank, the first fluid layer configured to receive additional fluid from the tank that increases a width of the first fluid layer to increase an elevation of the interface layer with respect to the base of the tank, the method comprising: receiving, from a sensor and by a processor communicatively coupled to the sensor, a value representing an amount of backscattered neutrons sensed by the sensor, the sensor attached to an external surface of a wall of the tank and adjacent a fluid outlet of the storage tank, the sensor configured to sense neutrons backscattered from at least one of the first fluid layer and the interface layer, the neutrons emitted by a neutron emitting device attached to the wall of the tank; comparing, by the processor, the value to a threshold; and actuating, by the processor and based on a result of comparing the value to the threshold, a valve fluidically coupled to the outlet of the storage tank to drain the first fluid layer from the storage tank while preventing the interface layer from leaving the storage tank. 2. The method of claim 1 , wherein receiving the value comprises receiving, from the sensor, the value sensed at a location between 1 to 3 inches above the fluid outlet of the storage tank. 3. The method of claim 1 , wherein actuating the valve comprises opening the valve or closing the valve to drain the first fluid layer while preventing the interface layer from leaving the storage tank. 4. The method of claim 1 , wherein the first fluid layer comprises a higher density than the second fluid layer such that the first fluid layer comprises more hydrogen per unit volume than the second fluid layer. 5. The method of claim 1 , wherein comparing the value to the threshold comprises comparing the value to a first threshold and to a second threshold lower than the first threshold, the first threshold representing a first amount of backscattered neutrons and the second threshold representing a second amount of backscattered neutrons lower than the first amount, and wherein actuating the valve comprises opening the valve when the value meets the first threshold and closing the valve when the valve meets the second threshold. 6. The method of claim 1 , further comprising, prior to actuating the valve, determining, by the processor and based on the comparison of the value to the threshold, that the interface layer is at the same elevation as the sensor or above the elevation of the sensor. 7. The method of claim 1 , wherein the neutron emitting device and the sensor are disposed in a neutron backscatter permanently coupled to the external surface of the wall of the tank, and wherein receiving the value comprises receiving the value from the neutron backscatter with the neutron emitting device continuously emitting neutrons into the storage tank. 8. The method of claim 1 , wherein the valve comprises a motor-operated valve and wherein actuating the valve comprises actuating a motor of the motor-operated valve. 9. The method of claim 1 , wherein the valve is coupled to a first pipe fluidically coupled to a second pipe fluidically coupled to the outlet of the tank, the second pipe comprising a second valve, and wherein actuating the valve comprises actuating the valve as the second valve remains closed. 10. The method of claim 1 , wherein the first fluid layer comprises a water layer, the second fluid layer comprises a hydrocarbon layer, and the interface layer comprises an emulsion layer. 11. An automatic dewatering system, comprising: a hydrocarbon storage tank comprising a fluid outlet, the tank carrying a first fluid layer comprising a first hydrogen concentration and a second fluid layer comprising a second hydrogen concentration different than the first hydrogen concentration, the first fluid layer separated from the second fluid layer by an interface layer, the first fluid layer disposed between the interface layer and a base of the storage tank, the first fluid layer configured to receive additional fluid from the tank that increases a width of the first fluid layer to increase an elevation of the interface layer with respect to the base of the tank; a neutron emitting device disposed above the fluid outlet of the storage tank adjacent the fluid outlet, the neutron emitting device configured to emit neutrons into the tank to be backscattered from at least one of the first fluid layer and the interface layer; a sensor attached to an external surface of a wall of the tank, the sensor disposed above the fluid outlet of the storage tank adjacent the fluid outlet, the sensor configured to sense neutrons backscattered from at least one of the first fluid layer and the interface layer; a valve fluidically coupled to the fluid outlet of the storage tank; and a processor communicatively coupled to the sensor and to the valve, the processor configured to compare a value received from the sensor to a threshold, the value representing an amount of backscattered neutrons sensed by the sensor, the processor configured to actuate, based on a result of comparing the value to the threshold, a valve fluidically coupled to the outlet of the storage tank to drain the first fluid layer from the storage tank while preventing the interface layer from leaving the storage tank. 12. The system of claim 11 , wherein the sensor is configured to sense the value at a location between 1 to 3 inches above the fluid outlet of the storage tank. 13. The system of claim 11 , wherein the processor is configured to open the valve or close the valve to drain the first fluid layer while preventing the interface layer from leaving the storage tank. 14. The system of claim 11 , wherein the first fluid layer comprises a higher density than the second fluid layer such that the first fluid layer comprises more hydrogen per unit volume than the second fluid layer. 15. The system of claim 11 , wherein the processor is configured to compare the value to a first threshold and to a second threshold higher than the first threshold, the first threshold representing a first amount of backscattered neutrons and the second threshold representing a second amount of backscattered neutrons higher than the first amount, and wherein the processor is configured to open the valve when the value meets the first threshold and close the valve when the valve meets the second threshold. 16. The system of claim 11 , wherein the sensor comprises a sensing surface comprising a height parallel to a height of the tank, the sensor configured to sense a change of an amount of backscattered neutrons as the interface layer moves in elevation across the height of the sensor. 17. The system of claim 11 , wherein the neutron emitting device and the sensor are disposed in a neutron backscatter permanently coupled to the external surface of the wall of the tank, and wherein the neutron emitting device is configured to continuously emit neutrons into the storage tank. 18. The system of claim 11 , wherein the valve is coupled to a first pipe fluidically coupled to a second pipe fluidically coupled to the outlet of the tank, the second pipe comprising a second valve, and wherein the processor is