Gamma-ray sensing probe using Cerenkov effect and system for identifying burnup of spent nuclear fuel assembly using the same

What is claimed is: 1. A system for identifying burnup of a spent nuclear fuel assembly, comprising: a plurality of gamma-ray sensing probes disposed to surround the perimeter of the spent nuclear fuel assembly, the gamma-ray sensing probes reacting to gamma rays coming from the spent nuclear fuel assembly and generating optical signals by the Cerenkov effect, said gamma-ray sensing probes comprising: an optical fiber disposed to face a gamma-ray test surface of a spent nuclear fuel assembly in a direction perpendicular to a lengthwise direction of the spent nuclear fuel assembly, the optical fiber reacting to gamma rays coming from the gamma-ray test surface and causing Compton scattering to emit light in the optical fiber by the Cerenkov effect; a scatterer extending along the length of, and formed to surround an outer circumferential surface of, the optical fiber, the scatterer reacting to gamma rays incident from the gamma-ray test surface of the spent nuclear fuel assembly and causing Compton scattering to produce Campton electrons, the Campton electrons pass through the optical fiber and generate light due to the Cerenkov effect in the optical fiber; and a collimator surrounding an outer circumferential surface of the scatterer and composed of a shielding material, the collimator having a slit groove formed at one side thereof, for passing gamma rays coming from a part of the gamma-ray test surface, for which measurement is required, through the scatterer; an optical fiber transmission line transmitting optical signals generated from the gamma-ray sensing probes; a lift driving part lifting the gamma-ray sensing probes in a direction lengthwise of the spent nuclear fuel assembly; an optical measuring instrument measuring the amount of light of the optical signals transmitted through the optical fiber transmission line; and a computational processing part analyzing the measurement results of the optical measuring instrument and calculating intensity of gamma rays coming from the spent nuclear fuel assembly, the computational processing part determining burnup of the spent nuclear fuel assembly based on the calculated intensity of the gamma rays. 2. The system of claim 1 , wherein: the optical fiber transmission line is disposed at an end of the optical fiber formed to extend from the gamma-ray sensing probe and includes an auxiliary optical fiber transmission line that is integrally coated with the optical fiber extending from the gamma-ray sensing probe via a cladding tube. 3. The system of claim 2 , wherein the computational processing part determines the intensity of gamma rays generated from a gamma-ray test surface by subtracting an amount of light measured by the auxiliary optical fiber from an amount of light measured by the optical fiber provided at the gamma-ray sensing probes and the optical fiber transmission line.