FR2591343A1 - PROCESS FOR DETERMINING THE OXYGEN / METAL RATIO IN AN OXIDE USED AS A NUCLEAR FUEL - Google Patents

Abstract

A method for determining the oxygen / metal ratio in a nuclear fuel oxide. A mixture of a nuclear fuel oxide and a metal flux is placed in a graphite crucible 2, this mixture is heated in the crucible in a reducing environment of an inert gas to melt the mixture and therefore produce carbon monoxide. carbon, the amount of carbon monoxide produced is precisely determined to calculate the amount of oxygen in the oxide, and the oxygen / metal ratio of this oxide is calculated from the calculated amount of oxygen. The invention finds its main application in the production of nuclear fuels. (CF DRAWING IN BOPI)

Description

PROCESS FOR DETERMINING THE OXYGEN / METAL RATIO IN

  AN OXIDE USED AS NUCLEAR FUEL.

  The present invention relates to a method for determining

  quickly, and with great precision, the ratio oxygen / metal (hereinafter called "ratio O / M" ') in an oxide

nuclear fuel.

  It is no exaggeration to say that the O / M ratio of a nuclear fuel oxide such as uranium oxide, plutonium oxide, thorium oxide or the like is

  important physical property, which influences the conductor

  temperature, the creep rate, the diffusion of the products of nuclear fission, the electrical conductivity, the spontaneous diffusion, etc., and also determines the value of

the nuclear fuel oxide.

  For example, when M is U (uranium), the speed of

  creep varies according to the ratio O / U. More specifically

  the creep rate increases with the O / U ratio. It is further known that an increase in the O / U ratio leads to higher electrical conductivity and lower activation energy. It is also known that the value of fTc k (T) dt, which is the value necessary to cause a melting or recrystallization, is lower the higher the ratio O / U. fTc k (T) dT is what is called the thermal conductivity integral, in which k (T) is the thermal conductivity at temperature T, Ts is the temperature of a fuel element on its surface and Tc is the temperature of a fuel element in its central part. Among the methods for determining the O / M ratio of a nuclear fuel, which are used in a conventional manner, mention may be made of X-ray diffractometry, where the quantity of oxygen present in the oxide is determined from the lattice constant, and a gravimetric method, in which one determines with the aid of a

  balance increases and decreases the amount of oxy-

  which result from an oxidation-reduction reaction.

  However, in the above conventional methods, the amount of oxygen is indirectly determined from the physical properties of an oxide as a nuclear fuel. These conventional methods are therefore disadvantageous because the determination errors are large and, furthermore, the analysis and determinations take a long time.

  The object of the invention is therefore to create a method capable of

  to determine directly, with a yield and accuracy

  high, in a shorter time than before, the

  O / M ratio of a nuclear fuel oxide.

  To this end, the invention relates to a method of placing a nuclear fuel oxide in a crucible of

  graphite, at the same time as a metal flux, and heated

  the mixture of oxide and metal flux is

  in the crucible, in a reducing environment of an inert gas such as argon or helium, so as to melt the mixture. The oxygen produced by the oxide under the effect of the reduction reaction reacts immediately with the carbon of the graphite crucible to form carbon monoxide. Thus, the amount of oxygen can be calculated by accurately determining the amount of carbon monoxide

  formed, and we can calculate from the quantity of oxy-

gene the ratio O / M.

  A powder of a metal, such as iron or tin, may be used as the metal flux for mixing with the nuclear fuel oxide. The use of this metal flux serves to lower the melting temperature of the nuclear fuel oxide, and to improve the uniformity

of the merger.

  Among the preferred apparatuses for determining the amount of carbon monoxide, there may be mentioned a nondispersive infrared gas analyzer, which takes advantage of the absorption of infrared radiation by carbon monoxide, and a thermal conductivity detector, which draws advantage of the difference in thermal conductivity between a

  carrier gas comprises an inert gas on the one hand, and the mono-

carbon dioxide on the other hand.

  The invention will be better understood in view of the description

  following description and the accompanying drawing, which represents an embodiment of the invention, a drawing in which the reference

  1 denotes a degassing furnace, in which is placed a crucible

  2. The degassing oven is constructed such that the contents of the graphite crucible 2 are melted using a heater (not shown). Among the heaters that can be used, mention may be made of

  a high frequency heater and a power source

  DC voltage for resistance heating,

  in which the resistance is the graphite crucible.

  A mixture of a nuclear fuel oxide, for example uranium dioxide, is placed in the graphite crucible 2

  and a metal flux, for example an iron powder.

  Then an inert gas, for example argon, is introduced into the degassing furnace, and the mixture in crucible 2 is melted by heating under an argon atmosphere. It should be noted in this connection that, as stated above, the melting point of the nuclear fuel oxide can be lowered by adding a metal flux. For example, when uranium dioxide is used alone, it starts to melt at

  temperature as high as 2850 C. In addition, the addi-

  a metallic flux allows it to begin to melt

at about 2500 C.

  Oxygen is produced by the oxide as part of a reduction reaction that accompanies the melting of oxide and flux. The presence of the reducing environment containing argon has the consequence that the produced oxygen reacts immediately with the carbon of the graphite crucible 2,

  to form carbon monoxide. We can express the reaction

  by the following equation: MO2 + flux + 2C (carbon or graphite crucible) reduction reaction> flux.M + 2CO o MO2 denotes a nuclear fuel oxide, fluxing refers to a flux consisting of a metal powder such as the iron or

  tin, C is carbon, and CO is carbon monoxide.

  The carbon monoxide thus formed is sent, together with the argon from the degassing furnace 1, into a dedusting filter 7, and then introduced into a carbon monoxide measuring apparatus 3, such as a gas analyzer. non-dispersive infrared, in which the amount of carbon monoxide in argon is accurately determined. If necessary, the value thus determined is

  recorder 4. A gaseous mixture consis-

  carbon monoxide and argon removed from the

  reil 3 of carbon monoxide dosing is discharged to

  outside after passing through a gas flow meter 5.

  The gas flow meter 5 is installed as an auxiliary, to check the constancy of the flow of the carrier gas (gas

  inert). With regard to evacuation, mentioned above,

  above, the gas mixture to the outside, it should be noted that, in the case of the analysis of a sample before irradiation (that is to say of a sample of UO2 before irradiation), it is sufficient to install a dust filter 7 because the oxygen is not in the activated state. However, when the analysis involves an irradiated sample, there is a risk that the sample contains FP gas (the nuclear fission product gas), and that the oxygen in the sample is in the activated state. In such a case, it is necessary to use a means of

  filtration, for example a HEPA filter (which-

  stops aerial particles less than 1 Nm), or

activated carbon filter.

  When determining the O / M ratio of a sample

  mixed oxide PuO2-UO2, the degassing oven 1 and the

  3 for carbon monoxide should be provided with a glove box 10 and an enclosure with openings

  free 20, shown in dashes on the drawing.

  Reference 6 designates a standard gas generator, used

  to calibrate the apparatus 3 for measuring carbon monoxide.

  More particularly, a gaseous mixture comprising mono-

  carbon dioxide gas and an inert gas, mixture in which the concentration of carbon monoxide is known, is first sent, as a standard gas, from the generator 6 to the apparatus 3 for measuring carbon monoxide, so

  to know the data indicated by the metering equipment 3.

  The results obtained are represented on a graph, and we use the linearity of this graph to use

  results obtained for calibration.

  The amount of oxygen CO (in% by weight) can be calculated from the amount of carbon monoxide CO (in% by weight), determined with the aid of the apparatus 3

  carbon monoxide. For this, we use equation (1)

after: W

(1 C

  C = WC + WO x Cco (where W0 is the atomic mass of oxygen and WC the

atomic mass of carbon.

  The ratio O / M (ratio R) can be determined from the amount of oxygen CO obtained by equation (1). For this purpose, equation (2) is used:

CO = W + W. 100

C W M 1 O

c0 M I

R = 100 O (2)

  o WM is the average atomic mass of the metal atom M

in an oxide MO2.

  It is also possible to calculate by automatic methods the ratio O / M. For this, the equations (1) and (2) above are programmed in a data processing unit (not shown), and the data which has been determined using the apparatus 3 is entered into the latter.

of carbon monoxide dosage.

  In addition, it is possible to carry out in a continuous and automatic way the determination of the oxygen / metal ratio according to the invention, by preliminary placing, in different graphite crucibles, different mixtures of a combustible oxide. the oxygen / metal ratio, and a metal flux, and then placing the crucibles on a carousel and subjecting the crucibles, one after the other in each test, to the furnace of

  degassing under the effect of rotation of the carousel.

  As has been said above, according to the present invention, the O / M ratio can be determined directly by extracting all of the oxygen in a nuclear fuel oxide, which increases the accuracy of the relative determination. conventional O / M ratio determination methods. In addition, since the operation of melting a nuclear fuel oxide sample, forming the carbon monoxide and making the determination can be performed in about 10 minutes per sample, the present invention can be remarkably shorten the time used in conventional processes, which required about 7 hours to 1 day per sample. In addition, the amount of the nuclear fuel oxide to be used as a sample may be between one tenth and one half of the quantities

  required by conventional methods. The present invention

  finally, the advantage of reducing the absorbed dose of radiation resulting from the manipulation of a nuclear fuel oxide, since the determination time is shorter, and

  the amount of sample to be used is lower.

  Although the process according to the invention is particularly

  effective in determining the amount of oxygen and the O / M ratio of a nuclear fuel oxide, it can also be used to determine the amount of oxygen and the ratio

O / M other oxides.

  Of course, the invention is not limited to the embodiments described above and shown, from which we can provide other modes and other forms.

  without departing from the scope of the invention.

tion.

Claims (6)

claims   A method for determining the oxygen / metal ratio in a nuclear fuel oxide, characterized by placing a mixture of a nuclear fuel oxide and a flux metal in a graphite crucible (2),   to heat this mixture in this crucible in an envi-   reducer of an inert gas, to melt this mixture and thus produce carbon monoxide, to accurately determine the amount of carbon monoxide   produced to calculate the amount of oxygen is   in the oxide, and to calculate the oxygen / metal ratio of this oxide from the calculated amount of oxygen 2. Method according to claim 1, characterized in that the nuclear fuel oxide is selected from the group comprising uranium oxide, plutonium oxide, oxide   of thorium and the mixed oxide of uranium and plutonium.   3. Method according to claim 1, characterized in that   said metal flux is selected from the group consisting of   iron powder and tin powder.   4. Process according to claim 1, characterized in that the inert gas is chosen from the group comprising argon and helium.   5. Method according to claim 1, characterized in that the mixture of the nuclear fuel oxide and the metal flux is heated by high frequency heating or resistance heating.   6. Method according to claim 1, characterized in that the amount of carbon monoxide is determined using a non-dispersive infrared gas analyzer or a non-dispersive infrared gas analyzer.   thermal conductivity detector.