International audienceNuclear heating measurements in Material Testing Reactors are crucial for the design of the experimental devices and the prediction of the temperature of the hosted samples. Indeed, nuclear heating is a key input data for the computer codes which simulate temperature reached by samples under irradiation. In the Jules Horowitz Reactor under construction at the CEA Cadarache, the maximal expected nuclear heating levels will be about 15 to 18 W/g and it will be necessary to measure this key parameter with the best accuracy. An experiment was led at the OSIRIS reactor to compare the measurements between the two most appropriate sensors for measuring nuclear heating in MTR; a differential calorimeter and a gamma thermometer. A specific differential calorimeter was designed for low nuclear heating and a standard gamma thermometer was used. Experimental results and Monte-Carlo simulations show that the two sensors are suitable even if the measured energy deposit is different in the two sensors. Finally, these comparisons between the measurements recall that it is primordial to precise in which material and environment the nuclear heating is measured to use this key parameter for designing experimental devices in MTR
Abstract-The nuclear radiation energy deposition rate (unit usually employed: W.g -1 ) is a key parameter for the thermal design of experiments on materials and nuclear fuel carried out in experimental channels of irradiation reactors, such as the French reactor in Saclay called OSIRIS or the Polish reactor named MARIA. In particular the quantification of nuclear heating allows the prediction of heat and thermal conditions induced in irradiated devices and/or structural materials. Various sensors are used to quantify this parameter, in particular radiometric calorimeters, also known as in-pile calorimeters. Two main kinds of in-pile calorimeter exist possessing two geometries and two measurement principles: the single-cell calorimeter and the differential calorimeter. The present work focuses on specific examples of these calorimeter types, from the step of their out-of-pile calibration (transient and steady experiments respectively) to the comparison between numerical and experimental results obtained from two irradiation campaigns (French and Polish reactors). The main aim of this paper is to propose a steady numerical approach to estimate the single-cell calorimeter response under irradiation conditions.
Gas concentration measurements by means of metal oxide microsensors represent a promising issue due to several advantages (size, low cost, power consumption, reliability…).However, improvements are required to increase performances of complete experimental systems including microsensor and testing chamber at least. This paper deals with the study of different size and shape configurations of gas testing chamber, by coupling 3D unsteady modelling and experiments in the case of a SnO 2 sensor with ethanol gas flow. The influence of the testing-chamber design on the gas flow hydrodynamics and on the system response is shown. A new 3D-printed prototype chamber (boat-shape design), as compared to the commonly used testing chamber (cross-shape design), leads to an increase of the dynamics, an enhancement of the gas concentration homogeneity and a significant reduction of flow recirculation and dead volumes. In this work we have shown that the optimization of the test chamber (volume and shape) makes it possible to get as close as possible to the real electrical characteristics of the sensor. Consequently thanks to these new achieved characteristics, the performances of the whole system are improved.
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