RU144391U1 - WORKING BODY OF THE CONTROL SYSTEM AND REACTOR PROTECTION AT FAST NEUTRONS - Google Patents

Abstract

1. The working body of the control and protection system of the fast neutron reactor, which includes a body and absorbing elements, one of which is located on the axis of the working body and is made in the form of a rod - a column of the absorber inside the steel shell, and the rest are located coaxially with the body and are made in the form of hollow cylinders - columns of absorbent tablets with a central hole, enclosed in inner and outer steel shells. 2. The working body according to claim 1, characterized in that the volume of the absorber, the thickness of the steel shells, as well as the size and composition of the gap between the absorber and the shell of the absorbing elements are selected based on the required parameters of the physical efficiency of the working body and the conditions for heat removal in it. Working body according to claim 1, characterized in that the absorbing elements contain different absorbing material, selected based on the required values of the efficiency of the working member. The working body according to claim 1, characterized in that the central absorbing element additionally contains a neutron moderator. The working body according to claim 1, characterized in that when boron carbide is used as an absorber material, its enrichment in the B isotope in the absorbing element is different based on the required values of the working member efficiency.

Description

The utility model relates to nuclear engineering, namely, to the working bodies of the control system and protection of fast fast neutron reactors, and is used to increase the safety and economic efficiency of the latter.

Known working body of the control and protection system (RO CPS) of previously operated and currently operating fast neutron reactors (RBN) [Walter A., Reynolds A. Fast neutron multiplier reactors: Trans. from English - M .: Energoatomizdat, 1986. 624 s] containing a shell in which a beam of identical rod absorbing elements (pels) and displacers are placed. Pels are a column of an absorber enclosed in a steel shell (mainly boron carbide), consisting of tablets.

The disadvantages of this design are the low volume fraction of the absorber in the RC CPS and the lack of the possibility of its increase. Thus, often, to obtain a PO of sufficiently high efficiency, it is necessary to use boron carbide with high enrichment in the ¹⁰ B isotope (up to 80-95%), which is an expensive material.

Known RO CPS [Ponomarneko V.B, Efremov A.I., Gadzhiev G.I. ect., Experience in development, operating and vaterial investigation of the BOR-60 rector control and safety rods, Proceeding of a Technical Committee meeting, Obninsk, Russian Federation, 3-7 July 1995, IAEA - TECDOC-884, 1996, p. 191-199], consisting of one absorbing element, which is an absorbent column enclosed in a shell, assembled from tablets of large diameter, comparable to the size of the reactor cell

This design RO CPS allows you to significantly increase the share of the absorber in the working body and, accordingly, its effectiveness.

The disadvantage of this design RO CPS are high temperatures and temperature gradients and, as a result, thermo-mechanical stresses in the absorber volume, which reduces the service life of the absorbing element.

The objective of the proposed technical solution is to increase the duration of the campaign of the reactor while increasing the safety of the reactor by increasing the volume fraction of the absorber in the working body of the control system and protection of the fast neutron reactor while maintaining acceptable heat removal conditions.

To solve this problem, a working body of the control and protection system for a fast neutron reactor is proposed that includes a body and absorbing elements located in it, one of which is made in the form of a rod and located on the axis of the working body, and the rest are made in the form of hollow cylinders and are aligned with the body. The core pel is an absorber column enclosed in a steel shell. The pel in the form of a hollow cylinder is a column of absorber tablets with a central hole enclosed in an inner and outer steel shell.

The volume of the absorber, the thickness of the shells of the coaxial cylinders, as well as the size and composition of the gap between the absorber and the shell of the absorbing elements, are selected based on the required parameters of the efficiency of the working body and the conditions for heat removal in it.

The central absorption element may further comprise a neutron moderator.

The material of the absorber (boron carbide, europium oxide, hafnium hydride, etc.) in different absorbing elements can vary and is selected based on the required values of the efficiency of the working body and the conditions of heat removal in it.

When using boron carbide as an absorber material, its enrichment by the ¹⁰ B isotope is selected for each pool based on the required values of the working body efficiency and heat removal conditions in it.

When the absorber is placed in the form of a cylindrical layer (ring), the integrated efficiency of the RC CPS increases due to the reduction of screening.

In the inventive design RO CPS there is the possibility of adding an absorber by increasing the thickness of the ring or by installing a rod pell in the Central cavity.

Estimated estimates show that during the operation of the RC CPS with an annular base, the conditions for heat removal from the external and internal sides of the absorber can be ensured by appropriate selection of the coolant flow rate.

The calculations showed that the most preferred option is to place an additional absorber in the central rod pele.

The volume of the absorber, the thickness of the steel shells, as well as the size and composition of the gap between the absorber and the shell of the absorbing elements, are selected based on the required parameters of the physical efficiency of the working body and the conditions for heat removal in it.

In addition, the central absorbing element may additionally contain a neutron moderator (for example, depleted boron carbide - enrichment production dumps), which will reduce the neutron energy and thus increase the neutron capture rate in a cylindrical (ring) pel. This will increase the efficiency of the RC CPS without adding an additional absorber. Thus, it is possible to reduce the cost of RO CPS, with a relatively low cost of the moderator.

In the proposed design of RO CPS, the absorber in the central peel can be partially or completely replaced with a neutron moderator (for example, depleted boron carbide - enrichment production dumps), which will reduce the neutron energy and thus increase the neutron capture rate in a cylindrical (ring) pele. This will increase the efficiency of the RC CPS without adding an additional absorber. Thus, it is possible to reduce the cost of RO CPS, with a relatively low cost of the moderator.

When using boron carbide as an absorber material, its enrichment by the ¹⁰ B isotope is selected for each pool based on the required values of the working body efficiency and heat removal conditions in it. The use of boron carbide of various enrichment in the annular and rod pallets provides additional opportunities for equalizing the heat release in the RC CPS and, accordingly, the temperature conditions of irradiation.

The claimed technical solution allows to increase the volume (mass) of the absorber in the RC CPS, as well as to ensure proper temperature conditions during operation.

The central core pel, which simultaneously serves as a coolant displacer, allows you to equalize the temperature field in the ring pel.

In the case of using boron carbide enriched in the ¹⁰ B isotope as the absorber, the claimed technical solution will allow using boron carbide with less enrichment without increasing the integrated efficiency of the RC CPS due to the increase in the absorber volume, which can significantly reduce its cost.

In cases where the high efficiency of a specific RC CPS, for example, AR AR, is not required, and the efficiency of one cylindrical (ring) pel is sufficient, the central absorbing element can be removed or replaced with a coolant displacer.

For fast neutron reactors with a relatively small transverse cell size (for example, BOR-60), a 2-element design consisting of one rod pellet and one pellet in the form of a hollow cylinder will be preferable. In fast neutron reactors with a large transverse cell size (for example, BN-1200, BREST) and, accordingly, RO CPS, it is possible to use a design with more than one cylindrical pellet to ensure acceptable heat removal conditions.

Thus, the claimed technical solution provides an increase in the volume fraction of the absorber in the RC CPS, which allows either to increase the physical weight of the CPS RC in order to:

1) obtaining the technical ability to increase the reactivity margin and, accordingly, the duration of the reactor campaign;

2) increased reactor safety;

3) reduce the cost of RO CPS.

The attached figure shows a cross section of the working body of the reactor control and protection system, where:

1 - rod (central) pel,

2 - ring pel.

As the calculations show when replacing the manual control member (RO PP) of the BOR-60 reactor, which consists of 7 core pellets containing boron carbide enriched in the ¹⁰ B isotope to ~ 80%. on a design with one element in the form of a ring, the efficiency of PO increases by ~ 4%.

When a rod pellet with a diameter of ~ 22 mm with boron carbide (enrichment in ¹⁰ B - 80% enrichment) is installed in the formed central cavity, the effectiveness of RR PP will increase by 30-35%.

When installing a central rod pad with a diameter of ~ 18 mm, it is possible to reduce the enrichment of boron carbide by ¹⁰ V to 60% without losing the integral efficiency of the PP PP, which significantly reduces the cost of the latter.

The working body of emergency protection (RO AZ) of the BN-600 reactor consists of 7 core pellets containing boron carbide enriched in the ¹⁰ B isotope to ~ 80%.

In the transition from the standard multi-element design of PO AZ to a design with one element in the form of a ring, the efficiency of PO increases by ~ 5%.

When a regular core pel with natural boron carbide (enrichment of ¹⁰ B ~ 19% enrichment) is installed in the central cavity, the efficiency of the PP PP will increase by ~ 9% relative to the standard multi-element design.

When installing a central rod pad with a diameter of ~ 35 mm with natural boron carbide (enrichment at ¹⁰ B ~ 19%), the efficiency of the PP RR will increase by ~ 11% relative to the standard multi-element design.

Claims (5)

1. The working body of the control and protection system of a fast neutron reactor, including a body and absorbing elements, one of which is located on the axis of the working body and is made in the form of a rod - an absorber column inside a steel shell, and the rest are coaxial to the body and made in the form of hollow cylinder-pillars of absorber tablets with a central hole enclosed in the inner and outer steel shells. 2. The working body according to claim 1, characterized in that the volume of the absorber, the thickness of the steel shells, as well as the size and composition of the gap between the absorber and the shell of the absorbing elements, are selected based on the required parameters of the physical efficiency of the working body and the heat removal conditions in it. 3. The working body according to claim 1, characterized in that the absorbing elements contain various absorbing material, selected based on the required values of the efficiency of the working body. 4. The working body according to claim 1, characterized in that the central absorbing element further comprises a neutron moderator. 5. The working body according to claim 1, characterized in that when using boron carbide as the material of the absorber, its enrichment by the ¹⁰ V isotope in the absorbing element is different based on the required values of the efficiency of the working body.