Electrically conductive fiber optic slickline for coiled tubing operations

We claim: 1. An electrically conductive fiber optic cable configured to be disposed within a flow path of coiled tubing, the coiled tubing accommodating a downhole tool for an application in a well at an oilfield, the fiber optic cable comprising: a polymer jacketed fiber optic thread disposed through a void space defined by a conduit of the fiber optic cable to support optical telemetry between surface equipment at the oilfield and the downhole tool; a plurality of coaxial, electrically conductive members helically wound about the conduit, wherein the plurality of electrically conductive members are configured to provide power to the downhole tool from the surface equipment, the plurality of coaxial, electrically conductive members located exteriorly adjacent the conduit in an un-insulated manner relative to the conduit; an insulating polymer layer over the plurality of coaxial, electrically conductive members; and a single metal based cladding layer extending circumferentially about the insulating polymer layer, wherein the single metal based cladding layer has a first thickness such that the single metal based cladding layer provides a durable shell for the insulating polymer layer. 2. The electrically conductive fiber optic cable of claim 1 , wherein the plurality of coaxial, electrically conductive members are configured to provide telemetry between the surface equipment and the downhole tool. 3. The electrically conductive fiber optic cable of claim 1 , wherein the polymer jacketed fiber optic thread is configured to directly provide a distributed measurement to the surface equipment, the distributed measurement selected from a category consisting of temperature sensing, pressure sensing, vibration sensing, strain sensing, and fluid velocity sensing. 4. The electrically conductive fiber optic cable of claim 1 , wherein the polymer jacketed fiber optic thread provides a distributed measurement to the surface equipment. 5. The electrically conductive fiber optic cable of claim 1 , wherein a metallic tube defines the conduit and accommodates the plurality of coaxial electrically conductive members thereover. 6. The electrically conductive fiber optic cable of claim 1 , wherein the plurality of coaxial electrically conductive members are jacketed by a polymer to protect the conduit from exposure. 7. The electrically conductive fiber optic cable of claim 1 , further comprising: a first protective polymer layer extending circumferentially about the insulating polymer layer; and a second protective polymer layer extending circumferentially about the single metal based cladding layer; and a second metal based cladding layer extending circumferentially about the second protective polymer layer, wherein the second metal based cladding layer has a second thickness such that the second metal based cladding layer forms the exterior surface of the fiber optic cable and provides a second durable shell for the second protective polymer layer, wherein the second metal based cladding layer is coupled to the downhole tool and used as a grounding return path for the downhole tool. 8. The electrically conductive fiber optic cable of claim 7 , wherein the first and second protective polymer layers are of a material selected from a group consisting of a reinforced carbon fiber, a fluoropolymer, and a foamed polymer. 9. The electrically conductive fiber optic cable of claim 1 , further comprising a second metal based cladding layer extending circumferentially about the first metal based cladding layer, wherein the second metal based cladding layer has a second thickness such that the second metal based cladding layer provides a second durable shell for the first metal based cladding layer, wherein one of the cladding layers is dedicated to power delivery and the other of the cladding layers is coupled to the downhole tool and used as a grounding return path. 10. The electrically conductive fiber optic cable of claim 1 , wherein the single metal based cladding layer forms an exterior surface of the fiber optic cable, is coupled to the downhole tool and is used as a grounding return path for the downhole tool. 11. A coiled tubing assembly for use in an application at a location in a well at an oilfield with surface equipment positioned at a surface of the well, the coiled tubing assembly comprising: coiled tubing; an electrically conductive fiber optic cable run through a flow path of the coiled tubing; and a downhole tool coupled to the coiled tubing for advancement to the location in the well, the downhole tool telemetrically coupling to a polymer jacketed fiber optic thread run through a void space defined by a conduit of the fiber optic cable, the telemetric optical coupling for communications with the surface equipment and electrically coupling to a plurality of coaxial, conductive members helically wound about the conduit of the fiber optic cable, the conductive members located exteriorly adjacent the conduit in an un-insulated manner relative to the conduit, the electrical coupling providing dedicated power to the downhole tool from the surface equipment for the application, wherein the fiber optic cable comprises an insulating polymer layer over the conductive members, and a single metal based cladding layer extending circumferentially about the insulating polymer layer, wherein the metal based cladding layer has a thickness such that the metal based cladding layer provides a durable shell for the insulating polymer layer, wherein the single metal based cladding layer forms an external surface of the fiber optic cable, wherein the cladding layer is coupled to and used as an electrical grounding return path for the downhole tool. 12. The coiled tubing assembly of claim 11 , wherein the downhole tool is a logging tool. 13. A method of performing a coiled tubing application at a location in a well at an oilfield, the method comprising: pumping a fiber optic cable through a flow path of a coiled tubing; physically coupling a downhole tool to the coiled tubing; communicatively coupling a polymer jacketed fiber optic thread through a void space defined by a conduit of the fiber optic cable to the downhole tool to support optical telemetric communications between the downhole tool and surface equipment at the oilfield; powerably coupling a plurality of coaxial, electrically conductive members adjacent the conduit of the fiber optic cable to the downhole tool to provide dedicated power thereto from the surface equipment, wherein the plurality of coaxial electrically conductive members are helically wound about the conduit and un-insulated relative to the conduit, wherein the fiber optic cable comprises an insulating polymer layer over the plurality of coaxial, electrically conductive members, a single metal based cladding layer extending circumferentially about the insulating polymer layer, and wherein the metal based cladding layer has a thickness such that the metal based cladding layer provides a durable shell for the insulating polymer layer; advancing the downhole tool to the location with the coiled tubing; and performing the coiled tubing application at the location. 14. The method of claim 13 , further comprising utilizing the surface equipment to transmit commands to and receive information from the downhole tool. 15. The method of claim 13 , further comprising utilizing the surface equipment to obtain data detected directly by the jacketed fiber optic thread. 16. The method of claim 13 , wherein the metal based cladding layer forms an exterior surface of the fiber optic cable, is coupled to the downhol