Real-time cathodic protection integrity monitoring sensor, system and method

The invention claimed is: 1. A system for real-time monitoring and control of cathodic protection (CP) levels including cathodic protection potential and current capacity, in underwater equipment the operation of which is controlled via a subsea production control system (PCS), wherein cathodic protection comprises a supplier configured to provide cathodic current to protected components of the underwater equipment, the system comprising: a distributed network of sensors installed on the underwater equipment, the sensors arranged to perform measurements of galvanic current and polarized potential between (i) a reference object and (ii) a sacrificial anode or a protected component of the underwater equipment; a subsea, electronic, cathodic protection control (CPC) unit comprising a plurality of input terminals and a processor configured to receive and individually process sensor signals indicative of changes in the CP levels, wherein the CPC unit uses the PCS for communication, wherein the CPC unit is in communicative contact with the cathodic current supplier and configured to initiate current control commands for regulating the cathodic current supplied to individual components or component groups of the underwater equipment in response to detected CP levels, and the sensors are powered by cathodic current supplied to the CP system. 2. The system of claim 1 , wherein the CPC unit is integrated in a subsea electronic module (SEM) of the PCS. 3. The system of claim 1 , wherein the plurality of sensors are connected to the CPC unit via a distributed network of the PCS. 4. A method for real-time monitoring and control of cathodic protection (CP) levels including cathodic protection potential and current capacity, in underwater equipment the operation of which is controlled via a subsea production control system (PCS), wherein cathodic protection comprises a supplier configured to provide cathodic current to protected components of the underwater equipment, the method comprising: arranging a distributed network of sensors configured for generation of voltage outputs indicative of changes in galvanic current and polarized potential between (i) a reference object and (ii) a sacrificial anode or a protected component of the underwater equipment; communicating the sensor outputs via the PCS to a cathodic protection control (CPC) unit; generating in the CPC unit current control commands for regulating the cathodic current supplied to individual components or component groups of the underwater equipment in response to detected CP levels; arranging each sensor with a reference electrode in electrical and electrochemical contact with a metal sensing element which has a defined area exposed to the water; and configuring the sensor to generate a first output voltage indicative of the polarized potential between the metal sensing element and the reference electrode, and a second output voltage (V 2 ) indicative of the galvanic current flowing to the metal sensing element from one of the sacrificial anode or the protected component. 5. The method of claim 4 , further comprising coupling the sensing element electrically to one of the sacrificial anode or the protected component via a resistor and a switch. 6. The method of claim 4 , further comprising cycling the supply of current to the sensors to prevent deposits on the sensing area. 7. A method for real-time monitoring and control of cathodic protection (CP) levels including cathodic protection potential and current capacity, in underwater equipment the operation of which is controlled via a subsea production control system (PCS), wherein cathodic protection comprises a supplier configured to provide cathodic current to protected components of the underwater equipment, the method comprising: arranging a distributed network of sensors configured for generation of voltage outputs indicative of changes in galvanic current and polarized potential between (i) a reference object and (ii) a sacrificial anode or a protected component of the underwater equipment; communicating the sensor outputs via the PCS to a cathodic protection control (CPC) unit; generating in the CPC unit current control commands for regulating the cathodic current supplied to individual components or component groups of the underwater equipment in response to detected CP levels; and operating the sensors on cathodic current supplied by the cathodic current supplier. 8. The method of claim 7 , further comprising regulating the CP levels individually for protected components of the underwater equipment via a topside operator or optionally from the CPC unit directly without involvement from the topside operator. 9. A method for real-time monitoring and control of cathodic protection (CP) levels including cathodic protection potential and current capacity, in underwater equipment the operation of which is controlled via a subsea production control system (PCS), wherein cathodic protection comprises a supplier configured to provide cathodic current to protected components of the underwater equipment, the method comprising: arranging a distributed network of sensors configured for generation of voltage outputs indicative of changes in galvanic current and polarized potential between (i) a reference object and (ii) a sacrificial anode or a protected component of the underwater equipment; communicating the sensor outputs via the PCS to a cathodic protection control (CPC) unit; generating in the CPC unit current control commands for regulating the cathodic current supplied to individual components or component groups of the underwater equipment in response to detected CP levels; and determining the status of the cathodic protection (CP) by comparing detected changes in galvanic current and polarized potential with the corresponding levels of a cathodic protection system in balance, wherein deviations from the levels of the balanced system are ranked in categories of adequate CP, suboptimal CP and inadequate CP.