Unbonded flexible pipe and an offshore system comprising an unbonded flexible pipe

What is claimed is: 1. An unbonded flexible pipe for transportation of fluids, the unbonded flexible pipe has a length along a longitudinal center axis, and a first and a second end, and a first end fitting connected to the first end, the unbonded flexible pipe comprises from inside and out an electrically conductive carcass, an electrically insulating innermost sealing sheath, at least one electrically conductive armor layer comprising at least one helically wound electrically conductive wire and an electrically insulating outer sealing sheath, at least the electrically conductive layers are mechanically terminated in the first end fitting and the pipe comprises electrical connections in the first end fitting arranged to apply a voltage over the electrically conductive layers which electrically conductive layers are electrically connected at a far position of the unbonded flexible pipe at a distance from the first end fitting of the unbonded flexible pipe to provide an electric circuit and wherein the electrically conductive carcass and the electrically conductive armor layer are selected such that a voltage drop V c over the electrically conductive carcass is larger than a voltage drop V a over the electrically conductive armor layer. 2. The unbonded flexible pipe of claim 1 , wherein V c >1.5 times V a . 3. The unbonded flexible pipe of claim 1 , wherein the first end fitting comprises a bore extending through a front end in which the electrically conductive layers are mechanically terminated, and through a rear end of the first end fitting, the rear end of the first end fitting comprises a flange for being connected to a production site structure in fluid connection with a flow path thereof, the rear end of the first end fitting comprises an annular wall surface defining the rear end of the bore of the first end fitting, wherein at least a part of the annular wall surface is electrically insulated from the electrically conductive carcass. 4. The unbonded flexible pipe of claim 1 , wherein an electric power blocking is arranged in the rear end of the bore of the end fitting. 5. The unbonded flexible pipe of claim 4 , wherein the electric power blocking is a valve. 6. The unbonded flexible pipe of claim 4 , wherein the electric power blocking is a sacrificial anode comprising a metal or a metal alloy which is less noble than the annular wall surface of the first end fitting. 7. The unbonded flexible pipe of claim 1 , wherein the electrical connections arranged to apply a voltage over the electrically conductive layers are arranged to be connected to a main power supply for applying the voltage over the electrically conductive layers in said first end fitting, the main power supply is a dual power supply wherein one sub-power supply is connected over one of the electrically conductive layers and a zero potential and it adds a high potential to said one of the electrically conductive layers and another sub-power supply is connected over the other one of the electrically conductive layers and the zero potential and it adds a low potential to said other one of the electrically conductive layers. 8. The unbonded flexible pipe of claim 1 , wherein the unbonded flexible pipe comprises electrical connections for applying a support power supply in the electric circuit at a distance from the main power supply. 9. The unbonded flexible pipe of claim 1 , wherein the unbonded flexible pipe comprises two or more pipe length sections which are mechanically and electrically connected via respective intermediate end fittings, each pipe length section comprises from inside and out an electrically conductive carcass length section, an electrically insulating innermost sealing sheath length section, at least one armor layer length section comprising a length section of the at least one helically would electrically conductive wire and an electrically insulating outer sealing sheath length section, wherein the respective length sections of the conductive layers are electrically interconnected to provide the electric circuit. 10. The unbonded flexible pipe of claim 1 , wherein the unbonded flexible pipe comprises a temperature sensor. 11. An offshore system comprising a production site structure and an unbonded flexible pipe suitable for transporting fluids from a subsea facility to the production site structure, the unbonded flexible pipe has a length along a longitudinal center axis, and a first and a second end, and a first end fitting connected to the first end, wherein the unbonded flexible pipe is connected to said production site structure via said first end fitting, the unbonded flexible pipe comprises from inside and out an electrically conductive carcass, an electrically insulating innermost sealing sheath, at least one electrically conductive armor layer comprising at least one helically wound electrically conductive wire and an electrically insulating outer sealing sheath, at least the electrically conductive layers are mechanically terminated in the first end fitting and the pipe comprises electrical connections in the first end fitting arranged to apply a voltage over the electrically conductive layers which electrically conductive layers are electrically connected at a far position of the unbounded flexible pipe at a distance from the first end fitting of the unbonded flexible pipe to provide an electric circuit and wherein the electrically conductive carcass and the electrically conductive armor layer are selected such that a voltage drop V c over the electrically conductive carcass is larger than a voltage drop V a over the electrically conductive armor layer. 12. The offshore system of claim 11 , wherein the flow path of the production site structure comprises an inflow flow path section surrounded by an inflow flow path wall surface which in at least a length section is electrically insulated. 13. The offshore system as claimed in claim 11 , wherein the system further comprises a main power supply for applying the voltage over the electrically conductive layers, the main power supply is electrically connected to at least one of the electrical connections to the electrically conductive layers in said first end fitting. 14. The offshore system as claimed in claim 11 , wherein the system further comprises a main power supply for applying the voltage over the electrically conductive layers, the main power supply is electrically connected to both of the electrical connections to the electrically conductive layers in said first end fitting. 15. The offshore system as claimed in claim 11 , wherein the system further comprises a main power supply for applying the voltage over the electrically conductive layers, the main power supply is a dual power supply wherein one sub-power supply is connected over one of the electrically conductive layers and a zero potential and it adds a high potential to said one of the electrically conductive layers and another sub-power supply is connected over the other one of the electrically conductive layers and the zero potential and it adds a low potential to said other one of the electrically conductive layers. 16. The offshore system as claimed in claim 11 , wherein the system comprises a support power supply in the electric circuit arranged at a distance from the main power supply, the support power supply is arranged to impress an electrical potential difference between the electrically conductive layers at the far position of the unbounded flexible pipe such that the impressed electrical potential at the far position of each of the respective electrically conductive layers is negative where the e