Spliced optical fiber with splice protection, current sensor with such spliced optical fiber and method for protecting a spliced optical fiber

The invention claimed is: 1. A spliced optical fiber comprising a first and a second polarization-maintaining optical fiber connected to one another at one of their ends by splicing, thereby forming a splice at their connection point, and a protection tube arranged around the spliced optical fiber and surrounding at least an uncoated section of the spliced optical fiber which includes the splice, a first end and a second end of the protection tube sealed to the spliced optical fiber by a first and a second sealing arrangement for protecting the splice against mechanical stress and/or moisture, the protection tube having such a length that an uncoated section of the spliced optical fiber comprising the splice and a coated section of the spliced optical fiber at each end of the uncoated section are arranged inside the protection tube, a first distance from the first end of the protection tube and/or from the first sealing arrangement to a position of the splice and a second distance from the position of the splice to the second end of the protection tube and/or to the second sealing arrangement being greater than or equal to a predefined minimum distance L m , the minimum distance L m satisfying the following equation: 4√{square root over ( X 0 X s )} A ( L m )= X m X 0 being a maximum guaranteed polarization extinction ratio of the splice, X s being a maximum guaranteed polarization extinction ratio at the sealed ends of the protection tube, A(L) being a coherence function of a length of the polarization-maintaining fiber and a Fourier transform of an optical power spectrum, and X m being a predetermined maximum allowable polarization extinction ratio variation. 2. The spliced optical fiber according to claim 1 , wherein the protection tube is made of a material having a thermal expansion coefficient which is substantially equal to a thermal expansion coefficient of the first and the second polarization-maintaining optical fiber. 3. The spliced optical fiber according to claim 1 , wherein the protection tube has a diameter in the range between 1 mm and 5 mm. 4. The spliced optical fiber according to claim 1 , wherein at least one of the first and the second sealing arrangements comprises an outer dual-shrink sleeve adapted to shrink radially upon exposure to heat, thereby sealing the protection tube containing the section of the spliced optical fiber which includes the splice against humidity. 5. The spliced optical fiber according to claim 1 , wherein a first outer dual-shrink sleeve of the first and sealing arrangement and/or a second outer dual-shrink sleeve of the second sealing arrangement each comprises an outer tube and an inner tube, wherein the first end and the second end of the protection tube are arranged between the inner tube and the outer tube of the respective first and second outer dual-shrink sleeves. 6. The spliced optical fiber according to claim 5 , wherein at least one of the first and the second sealing arrangements comprises a capillary sleeve arranged partially inside the protection tube around a section of the spliced optical fiber, wherein the capillary sleeve is sealed to the spliced optical fiber by an inner dual-shrink sleeve at a first end facing the splice and is sealed by the inner tube of the respective outer dual-shrink sleeve at a second end. 7. The spliced optical fiber according to claim 6 , wherein said first end of the capillary sleeve is arranged between an inner tube and an outer tube of the respective inner dual-shrink sleeve, wherein the capillary sleeve is chosen to be longer than the inner tube of the second outer dual-shrink sleeve in longitudinal direction. 8. The spliced optical fiber according to claim 7 , wherein the outer tubes of at least one of the dual-shrink sleeves are made of a material able to radially shrink upon application of heat and the inner tubes are made of an adhesive material able to melt upon application of heat, wherein the materials of the inner tubes and outer tubes of dual-shrink sleeves have such properties that during a heat-up process by application of heat with a predefined temperature the inner tubes partially melt before the outer tubes begin to shrink. 9. The spliced optical fiber according to claim 8 , wherein the spliced optical fiber is obtainable by a process comprising: connecting a first and a second polarization-maintaining optical fiber at one of their ends by a splice, utilizing a splicing procedure that guarantees a maximum polarization extinction ratio of the splice of X 0 ; arranging a protection tube around the spliced optical fiber such that the protection tube surrounds at least an uncoated section of the spliced optical fiber which includes the splice, wherein the protection tube has such a length that an uncoated section of the spliced optical fiber comprising the splice and a coated section of the spliced optical fiber at each end of the uncoated section are arranged inside the protection tube; and sealing a first and a second end of the protection tube to the spliced optical fiber by a first and a second sealing arrangement, utilizing a sealing procedure that guarantees a maximum polarization extinction ratio of the spliced optical fiber at the first and/or the second sealing arrangement of X s . 10. The spliced optical fiber according to claim 1 , wherein the spliced optical fiber is comprised in an optical fiber communication device or in an optical measurement device. 11. The spliced optical fiber according to claim 1 , wherein the spliced optical fiber is comprised in a fiber optic current sensor for measuring a current in a current-carrying conductor, the fiber optic current sensor comprising: a primary converter suitable to be arranged around the conductor, wherein the primary converter is connected to the first polarization-maintaining optical fiber of the spliced optical fiber, and a secondary converter comprising an opto-electronics unit and connected to the second polarization-maintaining optical fiber of the spliced optical fiber for generating light to propagate into the same and detecting light from it. 12. The spliced optical fiber according to claim 11 , wherein the fiber optic current sensor is configured for measuring AC currents or DC currents up to 600 kA in one of a circuit breaker, a substation, or an aluminium production installation. 13. The spliced optical fiber according to claim 1 , wherein the spliced optical fiber is formed by connecting two polarization-maintaining optical fibers, against mechanical stress and/or moisture, the splice of the spliced optical fiber protected by a process comprising: step a) positioning the spliced optical fiber into the protection tube, wherein the protection tube has such a length that the splice is located inside it at least at the predefined minimum distance from a first end and a second end of the protection tube; step b) sealing the first end of the protection tube around the spliced optical fiber by applying heat to a first outer dual-shrink sleeve arranged around a portion of the first end of the protection tube and a portion of the spliced optical fiber, thereby shrinking the first outer dual-shrink sleeve onto said portions; and subsequently step c) sealing a capillary sleeve around a portion of the spliced optical fiber in an area of the second end of the protection tube, wherein the capillary sleeve is positioned at least partially inside the protection tube, by applying heat to an inner dual-shrink sleeve arranged around a portion of that end of the capillary sleeve, which is nearest to the splice, and around a portion of the spliced optical fiber; and step d) sealing the