WO2023167611A1 - Method for producing ingots of zirconium alloys based on magnesiothermic sponge - Google Patents

Abstract

The invention relates to the field of metallurgy and can be used for making zirconium alloy ingots. Proposed is a method of producing ingots of zirconium alloys based on magnesiothermic sponge, which includes weighing and evenly distributing the components of a charge material in a die, pressing briquettes, forming a consumable electrode from said briquettes and making an ingot by repeated vacuum remelting, the method being characterized by the use of a niobium-containing alloying component that is a zirconium-niobium alloy in the form of shavings having a thickness of not more than 2 mm and a niobium content of from 10 to 65 wt%. The ingots have a uniform distribution of niobium, meet the safety criteria applicable to clad tubes for use in nuclear reactors, and increase the competitiveness of Russian fuel.

Description

Method for manufacturing ingots of zirconium alloys based on a magnesium-thermal sponge

The invention relates to the field of metallurgy and can be used for smelting ingots of zirconium alloys used in nuclear energy.

A known method for producing a zirconium-niobium oxygen-containing alloy, described in the description of the patent RU2227171, (MIC C 22 C 16/00, 1/03, publ. 20.04.2004). It includes obtaining a charge from a zirconium-containing material and niobium pentoxide as an oxygen-containing and main niobium-containing material, preparing the charge for melting, and obtaining an ingot.

One of the disadvantages of the known method is that electrolytic zirconium powder can be used as a zirconium-containing charge material. Its use in zirconium-based alloys used for the manufacture of cladding tubes of nuclear reactors leads to an increase in the oxidation rate of cladding tubes under design basis accidents LOCA (loss of coolant accidents) and a sharp decrease in their plasticity due to the presence of fluorine. As a basis for the alloy of a zirconium-containing material, along with electrolytic zirconium powder, it is also possible to use spongy zirconium, which does not contain such an impurity. But due to the fact that the density and fractional composition of the powder of niobium and spongy zirconium differ significantly (8.6 g / cm ³ and not more than 1 mm, 6.5 g / cm ³ and 2-25 mm, respectively), there is a difficulty in ensuring the distribution uniformity components in the volume of the charge briquette. However, the description of the method does not disclose the features of the process of forming sponge-based briquettes and does not provide data on the uniformity of the distribution of niobium in the resulting ingot. A known method for producing a zirconium-niobium alloy ingot (patent RU 2313591, publ. 27.12.2007). The known method first includes electron-beam melting of an ingot of a zirconium alloy - 6.5% niobium using the speed of production of a binary alloy of zirconium - 1% niobium and a niobium template, after which this ingot is transferred into shavings for further smelting of an ingot of an alloy of zirconium - 1% niobium.

The disadvantage of the known method is that when obtaining an ingot of zirconium alloy - 6.5% niobium, there is a limitation on the mass of the initially melted niobium template placed on top of the zirconium-containing material. The size of the template is limited by the diameter of the mold. This limitation, in turn, leads to the need to smelt a large number of zirconium - 6.5% niobium alloy ingots of small mass (about 80 kg) in industrial applications, which implies the presence of a significant number of electron beam furnaces, additional material and labor costs and is economically impractical.

The closest technical solution is a method for producing ingots from zirconium alloys based on a magnesium-thermal sponge (patent RU 2700892, publ. 23.09.2019). Alloying of the ingot is carried out by pressing at a specific pressure of at least 5000 kg / cm ² with ligature tablets with a diameter of 11 mm, containing niobium-containing material in the form of niobium powder, and, if necessary, zirconium-containing material in the form of electrolytic zirconium powder or zirconium sponge crushed to a particle size of not more than 2 mm .

One of the disadvantages of the known method is the use of zirconium electrolytic powder, which, even in small quantities, is an undesirable zirconium-containing material due to the presence of fluorine and the need to follow the safety criteria below and maintain the competitiveness of Russian fuel for nuclear reactors (for example, Nuclear Safety Rules for Reactor Plants nuclear power plants. NBY RU AS-89. PNAE-G-1-024-90). The use of a zirconium sponge with a fraction of no more than 2 mm on an industrial scale implies the availability of additional production facilities, equipment for grinding and sieving the sponge, as well as labor resources, which is not economically feasible. It should also be noted that the use of strong pellets based only on niobium powder (the variant without zirconium-containing material) creates the risk of incomplete assimilation of niobium in the ingot during two remelting and the formation of structural heterogeneity in the form of niobium-enriched areas in products, leading to their rejection.

The objective of the invention is to manufacture ingots of zirconium alloys based on a magnesium-thermal sponge, homogeneous in composition, meeting the safety criteria for operation in nuclear reactors and increasing the competitiveness of Russian fuel.

EFFECT: production of ingots of zirconium alloys based on a magnesium-thermal sponge, homogeneous in composition due to the replacement of a niobium-containing component in the form of niobium powder in the charge with shavings of an alloy zirconium-niobium alloy with a given niobium content.

The technical result is achieved by using a method for manufacturing ingots of zirconium alloys based on a magnesium-thermal sponge, including weighing and uniform distribution of charge components in a mold, pressing briquettes, forming a consumable electrode from briquettes and melting an ingot by repeated vacuum remelting, characterized in that as alloying niobium-containing component is used alloy zirconium-niobium alloy in the form of chips with a thickness of not more than 2 mm with a niobium content of 10 to 65 wt.%.

Ingots of ligature zirconium-niobium alloy are obtained by double vacuum remelting, while as a zirconium-containing material a magnesium-thermal zirconium sponge and/or zirconium iodide and/or zirconium production turns are used, and then the ingots are converted into shavings.

When pressing briquettes for the manufacture of ingots of zirconium alloys, after batch weighing of the charge components, the chips of the master alloy zirconium-niobium alloy are evenly distributed in the mold among the remaining charge components: zirconium-containing material and other alloying components, if any.

The use of shavings of ligature zirconium-niobium alloy with a thickness of not more than 2 mm ensures its complete dissolution and assimilation during repeated vacuum remelting.

The content in the ligature zirconium-niobium alloy of niobium is less than 10 wt.% requires the introduction of a significant amount of ligature zirconium-niobium shavings cut from such an ingot into the briquette, which reduces the mechanical strength of the briquette.

When the content of niobium in the ligature zirconium-niobium alloy is more than 65 wt.%, there is a danger of incomplete dissolution of the ligature zirconium-niobium shavings cut from such an ingot, due to the high melting temperature of the alloy (more than 1970 ° C) and, as a result, the appearance of structural inhomogeneity in the form of areas enriched with niobium in products.

The implementation of smelting according to the closest technical solution and the proposed method is shown on examples of manufacturing industrial ingots of zirconium alloy EPO o.ch. according to TU 001.433-2014 with niobium content limits from 0.9 to 1.1 wt.% (table 1).

Example 1 (the closest technical solution).

The smelting of the ingot was carried out according to the approved normative technological documentation.

Ligature tablets weighing 54.5 g and 35 mm in diameter each were pressed on a press using a niobium-containing material in the form of niobium powder and other alloying components. EPO zirconium alloy ingot charge: zirconium-containing materials - magnesium-thermal sponge, pieces of iodide zirconium and shavings of zirconium production turnovers; for doping - pressed tablets.

The process of manufacturing an ingot of zirconium alloy EPO o.ch. included: separate weighing of zirconium-containing materials for each briquette weighing 22.281 kg with the addition of 10 ligature tablets, their uniform distribution in the mold, pressing the briquettes, welding the briquettes in a vacuum unit into consumable electrodes and melting the ingot by double vacuum remelting.

Example 2 (the claimed method).

A ligature zirconium-niobium alloy with a niobium content of 10.3 wt.% was obtained according to the scheme: a sample of niobium powder was poured into a zirconium production turnover tube and compressed by rolling. The tube was placed in the center of zirconium iodide rods, tied with zirconium wire, and the ingot was melted by double vacuum remelting. The manufactured ligature zirconium-niobium ingot was sharpened on a lathe into chips no more than 2 mm thick. Chips after crushing in a crusher to a length of not more than 100 mm, degreasing and magnetic separation were used as part of the charge for smelting a zirconium ingot of an EPO alloy of special purity.

Charge of ingot of zirconium alloy EPO o.ch.: zirconium-containing material - magnesium-thermal sponge; niobium-containing material in the form of shavings of ligature zirconium-niobium alloy with a thickness of not more than 2 mm, other alloying components (2.029 kg per briquette weighing 22.236 kg).

The process of manufacturing an ingot of zirconium alloy EPO o.ch. included: separate weighing of the charge components for each briquette weighing 22.236 kg, uniform distribution of chips of the ligature zirconium-niobium alloy in the mold among the magnesium-thermal sponge and other alloying components, pressing the briquettes, welding the briquettes into vacuum installation into consumable electrodes and subsequent smelting of the ingot by double vacuum remelting.

Example 3 (the claimed method).

A ligature zirconium-niobium alloy with a niobium content of 40.1 wt.% was obtained according to the following scheme: briquettes were pressed from a mixture of zirconium magnesium-thermal sponge and niobium production turnover chips, from which a consumable electrode was formed by electron beam welding and the ingot was melted by double vacuum remelting. Ligature zirconium-niobium ingot was sharpened on a lathe into chips no more than 2 mm thick. Chips after crushing in a crusher to a length of not more than 100 mm, degreasing and magnetic separation were used as part of the charge for smelting an ingot of zirconium alloy E110 o.ch.

Charge of ingot of zirconium alloy EPO o.ch.: zirconium-containing material - magnesium-thermal sponge; niobium-containing material in the form of shavings of ligature zirconium-niobium alloy (0.571 kg per briquette weighing 21.293 kg), other alloying components.

The process of manufacturing an ingot of zirconium alloy E110 o.ch. included the operations indicated in example 2.

Example 4 (the claimed method).

A ligature zirconium-niobium alloy with a niobium content of 64.6 wt.% was obtained according to the scheme: a niobium ingot was tied with zirconium iodide rods and the ingot was melted by double vacuum remelting. Ligature zirconium-niobium ingot was sharpened on a lathe into chips no more than 2 mm thick. Chips after grinding in a crusher to a length of not more than 100 mm, degreasing and magnetic separation were used as part of the charge for smelting an ingot of alloy E110 o.ch.

EPO zirconium alloy ingot charge: zirconium-containing materials - magnesium-thermal sponge and zirconium production turnover shavings; niobium-containing material in the form of alloy shavings zirconium-niobium alloy (0.324 kg per briquette weighing 22.748 kg), other alloying components.

The process of manufacturing an ingot of zirconium alloy EPO o.ch. included the operations indicated in example 2.

From the data in Table 1, it follows that the uniformity of the distribution of niobium during the smelting of ingots of the zirconium alloy EPO v.p. based on a magnesium-thermal sponge using a niobium-containing material in the form of a ligature zirconium-niobium shaving and ligature tablets is on the same level.

The given data testify to the solution of the task and the receipt of a new technical result: the creation of a method for manufacturing ingots of zirconium alloys based on a magnesium-thermal sponge, homogeneous in composition, using as a niobium-containing component chips of an alloy zirconium-niobium alloy of a given composition.

Ingots of a zirconium alloy based on a magnesium-thermal sponge of the specified quality ensure that the manufactured cladding pipes of nuclear reactors comply with the safety criterion under design basis accidents LOCA (Loss of Coolant Accidents) during operation in nuclear reactors, which increases the competitiveness of Russian fuel.

Table 1 - The results of the smelting of ingots of the EPO alloy o.ch. according to TU 001.433-2014

Claims

CLAIM

1. A method for manufacturing ingots of zirconium alloys based on a magnesium-thermal sponge, including weighing and uniform distribution of charge components in a mold, pressing briquettes, forming a consumable electrode from briquettes, and melting an ingot by multiple vacuum remelting, characterized in that a master alloy is used as an alloying niobium-containing component zirconium-niobium alloy in the form of chips with a thickness of not more than 2 mm with a niobium content of 10 to 65 wt.%.

2. The method according to claim 1, characterized in that when melting ingots of zirconium alloys, a magnesium-thermal zirconium sponge and/or zirconium iodide and/or zirconium production turns are used as a zirconium-containing material.

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SUBSTITUTE SHEET (RULE 26)