RU2153710C1 - Pressure-tube reactor core and fuel assembly - Google Patents

Abstract

FIELD: nuclear engineering. SUBSTANCE: uranium-graphite reactor core is built up of fuel assemblies with fuel elements composed of uranium dioxide doped with erbium oxide Er₂O₃. Erbium oxide content in nuclear fuel is 0.46 to 0.64 mass percent with respect to erbium at mass proportion of U-235 in nuclear fuel between 2.6 and 2.8 mass percent. Optimal content of erbium oxide in nuclear fuel of fuel assembly is 0.5 0.04 or 0.6 0.04 mass percent with respect to erbium. Such composition provides for reducing number of fuel assemblies per unit of generated energy and amount of spent nuclear fuel, decreases steam coefficient of reactivity and variations in energy release, reduces maximal linear load on fuel elements. EFFECT: improved efficiency and fuel burn-up. 2 cl

Description

 The technical field to which the invention relates.

The invention relates to nuclear engineering, in particular to the design of the active zones and fuel assemblies of channel RBMK uranium-graphite reactors (high-power channel reactor), which use nuclear fuel based on uranium dioxide with the addition of erbium oxide (Er ₂ O ₃ ).

 The prior art.

 An analysis of the causes of the accident at the Chernobyl nuclear power plant showed that catastrophic consequences were caused by the flaws in the design of the rods, regulation, and suboptimal uranium-graphite ratio. As a result, the steam reactivity coefficient was (4 - 5) β. After the accident, measures were taken at all reactor units with RBMK-type reactors to improve reactor safety. At the first stage, the steam reactivity coefficient was reduced to 1 β due to loading (52-54) of additional absorbers (DP) in RBMK-1500 and about 80 DP in RBMK-1000 and increasing the operational reactivity margin to 55 rods in RBMK-1500 and 45 rods in RBMK-1000. In this way, an uncontrolled increase in instantaneous neutron reactor power in the event of a probable dehydration of the core in an accident with a loss of coolant was practically eliminated.

 An increase in the number of additional absorbers in the core led to a significant decrease in the depth of fuel burnup and, as a result, to a deterioration in the economic characteristics of the fuel cycle. The burnup depth of the unloaded fuel decreased by about 25%. In addition to direct economic losses due to undercooling of fuel, the fuel problem has become more acute, since an increase in the rate of fuel overloads has led to an accelerated filling of spent fuel storage pools.

 At the second stage, RBMK reactors switched to fuel with uranium-235 enrichment of 2.4%. This made it possible to achieve the design burnup depth and significantly improve the fuel cycle efficiency.

 At the same time, studies were conducted to find a more economical way to reduce the steam reactivity coefficient instead of using additional absorbers.

 It is known that the active zones of water-cooled reactors can be formed from fuel assemblies containing fuel of various compositions with the addition of a burnable absorber, which makes it possible to compensate for reactivity, equalize energy release over the volume of the active zone and maintain the temperature coefficient of reactivity at a given level. Rare earth elements and their oxides, in particular erbium, are used as burnable absorbers (WO 95/04994 A1, 1995).

 Erbium, when used as a burnable absorber, unlike other rare-earth elements, is introduced into nuclear fuel in much lower concentrations, which positively affects the physical, thermal and technological properties of the fuel. In particular, the addition of erbium to the fuel has a weak effect on a factor such as the thermal conductivity of the fuel.

 The active zone of a channel nuclear reactor cooled by water is known, formed from fuel assemblies containing fuel elements with fuel in the form of uranium oxide, which contains erbium with a concentration of from 0.3 to 0.8% (see RU 2065627, C, 1996).

 Currently, a number of measures are being implemented at RBMK reactors aimed at further improving the core. In particular, the transition to new control rods with a belt link is underway, the operation of fuel assemblies with spacer grids of zirconium alloy instead of stainless steel begins, issues of the possibility of reducing the operational reactivity margin are studied. An alternative to maintaining DP in the core is to increase the erbium content in the fuel. In order for the increase in the erbium content of the additive in the fuel not to lead to losses in fuel burnup, it is necessary to simultaneously increase fuel enrichment.

 The introduction of erbium into the fuel of a RBMK channel nuclear reactor allows one to reduce the value of the steam reactivity coefficient.

 The presence of erbium in RBMK fuel allows the replacement in the core of at least part of additional absorbers (DP) with working fuel assemblies, which increases the fuel burnup depth.

 In addition, erbium as a neutron absorber does not burn out as intensely as, for example, gadolinium or boron, and retains its effect on the steam reactivity coefficient for most of the campaign. At the same time, the addition of erbium to the fuel reduces the maximum power of the channels and evens out the energy release in the core.

The closest in technical essence and the achieved result to the described invention is the core of a channel nuclear reactor formed from fuel assemblies, at least some of which contain fuel elements with nuclear fuel in the form of uranium dioxide with the addition of erbium oxide (Er ₂ O ₃ ) ( see Mezhuev V.A. et al. Some aspects of the design and manufacturing technology of fuel assemblies for power reactors with increased life and increased reliability. Atomic energy, vol. 84, issue 2, February 1998, p. 126, 127).

 In the known fuel assembly of a channel nuclear reactor, the enrichment of uranium is from 2.4 to 2.6%, and the erbium content in the fuel is 0.41% by mass. Adding erbium oxide to the fuel allows replacing additional absorbers with standard fuel assemblies, which improves the parameters of the core. The use of nuclear fuel with the addition of erbium and increased enrichment of uranium can significantly increase the burnup depth of nuclear fuel.

 It is obvious that when increasing the number of additional absorbers removed from the core and replacing them with fuel assemblies with uranium-erbium fuel, it is necessary to increase the percentage of erbium additive accordingly. Moreover, with an increase in the number of removable absorbers, their absence should be compensated for by an increase in the erbium content in the fuel. In turn, an increase in the erbium content should be compensated by an increase in the degree of fuel enrichment.

 However, with an arbitrary choice of the ratio between the increased values of fuel enrichment and the content of the erbium additive, a situation may arise when it is established, for example, by calculating that the required number of DPs cannot be removed from the core. Indeed, without coordinating the relationship between fuel enrichment and the content of erbium additive and when unloading the required number of DPs, a sharp decrease in the burnup depth is possible. Especially negative factors will manifest themselves with small amounts of fuel enrichment and with a significant erbium content in the fuel.

 SUMMARY OF THE INVENTION

 The objective of the present invention is to develop and create a core and a fuel assembly of a channel nuclear reactor with improved reliability, safe operation, as well as improved economic performance.

 As a result of solving this problem, new technical results can be obtained, namely that fuel burnup is increased, the consumption of fuel assemblies per unit of generated energy is reduced and the volume of spent nuclear fuel is reduced, the value of the steam reactivity coefficient and uneven energy release are reduced, and the maximum linear load on fuel elements.

These technical results are achieved in that in the core of a channel nuclear reactor formed of fuel assemblies, at least some of which contain fuel elements with nuclear fuel in the form of uranium dioxide with the addition of erbium oxide (Er ₂ O ₃ ), the content of erbium oxide in nuclear fuel is from 0.46 to 0.64 wt.% erbium with a conditional mass fraction of U-235 in nuclear fuel from 2.6 to 2.8 wt.%, and in the fuel assembly of a channel nuclear reactor containing fuel elements with dual fuel uranium ishi supplemented with erbium oxide (Er ₂ O _3), erbium oxide content in nuclear fuel is 0.5 ± 0.04 wt.% or 0.6 ± 0.04 wt.% of erbium, at a weight fraction of the conditioned U- 235 in nuclear fuel from 2.6 to 2.8 wt.%
A distinctive feature of the described invention is as follows. Adding erbium to the fuel can significantly reduce the steam reactivity coefficient in RBMKs, because the ¹⁶⁷ Er isotope, whose concentration is 22.9%, has a strong resonance at a neutron energy of 0.47 eV. When the density of the coolant decreases, the neutron spectrum shifts toward the resonance and the neutron absorption in erbium increases. This is due to the fact that the rate of neutron deceleration decreases, since deceleration in water does not occur, and the role of graphite, which has an operating temperature (200-250) ^o C higher than water, increases in the formation of the spectrum. Although the ¹⁶⁷ Er resonance is far from the maximum of the Maxwell spectrum, the neutron flux in the resonance region noticeably increases with dehydration. Thus, a shift of the spectrum to a region of higher energy leads to an increase in neutron absorption by ¹⁶⁷ Er. All this leads to an increase in the negative component of the steam reactivity coefficient. The more erbium in the fuel, the lower the steam reactivity coefficient and the higher the safety of RBMK operation.

 However, on the other hand, an increased erbium content in the fuel reduces fuel burnup, as spurious neutron absorption increases. Therefore, the increased erbium content should be compensated for by the corresponding enrichment of nuclear fuel. For this, a clear relationship is established between fuel enrichment and the erbium content in it.

 It was found that when the erbium content in the fuel of the core from 0.46 to 0.64 wt.% Erbium, the conditional mass fraction of U-235 in the nuclear fuel of the core should be from 2.6 to 2.8 wt.%. Otherwise, the above technical results cannot be realized due to the lack of a certain correspondence between the erbium content in the core fuel and its enrichment.

 In addition, it was substantiated that when forming the core during unloading the required number of additional absorbers and replacing them with fuel assemblies containing erbium, it was necessary that the content of erbium oxide in the nuclear fuel of the fuel assembly be 0.5 ± 0.04 weight. % or 0.6 ± 0.04 wt.% erbium, with a conditional mass fraction of U-235 in nuclear fuel from 2.6 to 2.8 wt.%. With the indicated ranges of erbium content in nuclear fuel and its enrichment, the best operating conditions for the core will be ensured and the coefficient of fuel consumption will be improved by replacing the required number of DPs with fuel assemblies without compromising any parameters of the core and fuel assemblies.

 Information confirming the possibility of using the invention.

 The described active zone of a channel nuclear uranium-graphite reactor is formed by known means (unloading and loading machine) from fuel assemblies. At the same time, during the operation of the active zone, burned-out fuel assemblies are replaced with fresh ones, as well as the discharge of fuel assemblies and the installation of fuel assemblies containing erbium in nuclear fuel in their place. The erbium oxide content in nuclear fuel of at least part of fuel assemblies is from 0.46 to 0.64% by weight of erbium with a conditional mass fraction of U-235 in nuclear fuel from 2.6 to 2.8% by weight. Loading and operation is accompanied by periodic measurements of the neutron-physical characteristics of the core, as well as the operability of the new fuel. The calculations showed that there is a decrease in the steam reactivity coefficient. Despite the increase in enrichment from 2.6 to 2.8%, the power of fuel assemblies with erbium additive does not exceed the power of fuel assemblies without erbium and the power of fuel assemblies with a lower erbium content.

 Replacing all the standard fuel assemblies with assemblies with a high erbium content will allow to unload all airplanes from the core.

The described fuel assembly of a channel nuclear reactor is manufactured in a known manner using conventional means on standard equipment. The manufacturing process of the assembly involves the production of fuel elements filled with tablets of uranium dioxide (UO ₂ ) with the addition of erbium oxide (Er ₂ O ₃ ). The fuel should have a certain phase composition, average grain size, maximum size of unreacted particles and other standard parameters.

 The manufacturing technology of nuclear fuel pellets is as follows. In the mixer, in particular the blade type, a two-component mixture of uranium dioxide is prepared with a conditional mass fraction of U-235 in nuclear fuel from 2.6 to 2.8 weight. % and erbium oxide. Moreover, such an amount of erbium oxide is added to nuclear fuel so that its content in nuclear fuel is 0.5 ± 0.04 wt.% Or 0.6 ± 0.04 wt.% Erbium. The mixture is then mixed with a standard plasticizer. Then granulate the mixture with a plasticizer, followed by grinding the granules and sieving at the stage of preparation of the press powder. After drying the press powder, tablets are pressed and sintered. The resulting tablets equip the fuel elements included in the fuel assemblies.

 At all stages of the manufacture of fuel assemblies, their parameters are monitored. The control of erbium content in nuclear fuel can be carried out by various methods, for example, by X-ray radiometric method.

Claims (2)

1. The core of the channel nuclear reactor, formed from fuel assemblies, at least some of which contain fuel elements with nuclear fuel in the form of uranium dioxide with the addition of erbium oxide (Er ₂ O ₃ ), characterized in that the content of erbium oxide in nuclear fuel ranges from 0.46 to 0.64 wt.% erbium with a conditional mass fraction of U-235 in nuclear fuel from 2.6 to 2.8 wt.%. 2. The fuel assembly of the channel nuclear reactor containing fuel elements with nuclear fuel in the form of uranium dioxide with the addition of erbium oxide (Er ₂ O ₃ ), characterized in that the content of erbium oxide in nuclear fuel is 0.5 ± 0.04 or 0, 6 ± 0.04 wt.% Erbium, with a conditional mass fraction of U-235 in nuclear fuel from 2.6 to 2.8 wt.%.