NO115933B - - Google Patents

Description

Annealed nickel-chromium alloys with resistance equal to stress-corrosion attack from aerated high-purity water under pressure.

Various articles such as pressure vessels, heat exchangers and steam generators, or parts of such articles, are exposed during use to high-purity water under pressure at elevated temperatures. These articles and parts can advantageously be produced from nickel-chromium alloys, e.g. alloys containing approx. 20% chromium, or of nickel-chromium iron alloys, e.g. alloys containing from 75 to 85% nickel, 14 to 16% chromium and up to 8% iron.

High-purity water, by which expression is understood here water that has a content of total solids of less than approx. 1 part per mil-lion by weight and which has been distilled, deionized or otherwise treated to have a resistivity of 500,000 ohm-cm or higher is normally oxygen-free. However, it has recently been announced that, on the basis of laboratory tests, if the water is Kfr. -'10b-39/22 is contaminated with oxygen and is under pressure at elevated temperatures, e.g. 150°C and above, and particularly in the 300 to 350°C range, nickel-chromium and nickel-chromium iron alloys exposed to the action of the water under these conditions will be prone to irritant granular cracking as a result of stress corrosion cracking. This cracking is also favored by other factors, and one of these is the presence of clefts or slits or cracks in the surface of the alloys. The presence of such crevices in an alloy which is sensitive to stress corrosion attack has the undesirable result that the corrosion product will be able to collect in these crevices (the so-called "crevice build-up") and adversely affect moving parts which have a small clearance tolerance. However, it is extremely difficult, if not impossible, to avoid the appearance of such gaps and other surface defects on finish-treated parts produced from such parts. Another factor that favors stress corrosion attack is that the alloys have previously become sensitive or sensitized by heating in the temperature range 425 to 800°C, as e.g. takes place as a result of welding processes, so-called welding seam sensitivity.

It requires elaborate precautions and the exercise of great care to keep highly pure water free of oxygen. This pure water is used to an increasing extent at elevated pressures and temperatures in nuclear equipment, e.g. nuclear power plants, and the careful work that is carried out to prevent water contamination during use is assumed to be the reason why stress corrosion attacks do not occur in practice on such equipment. However, the possibility of contamination with oxygen cannot be completely ruled out and, as a result of the very serious consequences that could result from stress corrosion cracking of the components and vessels in nuclear fission facilities, there is a need for alloys with increased resistance to stress corrosion-<- > attack by aerated high-purity water under pressure at elevated temperatures to reduce this risk. It is an object of the present invention to provide such alloys.

In accordance with the foregoing, the invention proceeds

out on annealed alloys with similar resistance to stress-corrosion attack from aerated high-purity water under pressure at high temperatures, especially for use in nuclear reactors, and the characteristic of the alloys is that they contain from 14 to 30% chromium, from 0 to 50% iron , from 0.003 to 0.05% aluminum, from 0.005 to 0.15% titanium, from 0.01 to 0.3% silicon and from 0.01 to 0.15% carbon, while the rest except impurities and residual deoxidizing substances is nickel in an amount of at least 30%, and in which if the carbon content

exceeds 0.03%, the grain size and hardness are represented by an f; point within the shaded area on Figure 1 in the attached drawing,

v and where the grain size and hardness would if the alloy was heated to 700 oC for 1 hour and air cooled, is represented by a point within [; the shaded area in fig. 2. j

Preferably, the iron content does not exceed 25%. A particularly advantageous alloy contains from 14 to 25% chromium, 1 to 8% iron, 0.005 to 0.025% aluminum, 0.01 to 0.1% titanium, 0.01 to 0.25% silicon and 0.01 to 0 , 1% carbon, while the rest, apart from impurities and residual deoxidising substances, is nickel.

The nickel-chromium and nickel-chromium iron alloys thus contain controlled amounts of aluminum and titanium smaller than those normally introduced into such alloys to deoxidize them and improve their hot workability, together with small controlled amounts of silicon.

In the attached drawings, the hardness in the Vicker scale is plotted against the grain size in the ASTM scale and the hatched areas below and to the left of the line AB in Figure 1 represent the desired correlation between the hardness and grain size in annealed alloys, i.e. after rapid cooling from an annealing heat treatment. The dashed area below and to the left of line CD in Figure 2 similarly represents the desired correlation between hardness and grain size after a sensitizing heat treatment comprising heating at 700°C for 1 hour and air cooling.

The grain size and hardness of the alloys are important, as relatively soft, fine-grained alloys tend to show greater resistance to stress corrosion cracking. The grain size is significant because the susceptibility or tendency to stress corrosion attack depends on the concentration of carbides at the grain boundaries. The smaller the grain size, the larger the grain boundary area over which a certain amount of carbides is distributed and the lower the carbide concentration. For the same reason, the carbon content in a coarse-grained alloy is advantageously lower than the carbon content in a fine-grained alloy. Whatever the grain size, the carbon content is advantageously as low as possible and preferably should not amount to more than -*0.03%. If the carbon content exceeds 0.03%, it is not sufficient just to ensure that the alloys have the composition stated above, but also the grain size and hardness of the alloys, in the annealed state in which they are normally used, must be represented. of a point within the dashed area in Figure 1. Furthermore, they must also satisfy the requirement that if they are sensitized or sensitized by heating to 700°C for 1 hour and then air-cooled, the grain size and hardness must be represented by a point within the more limited dashed area in Figure 2. The reason for this is that a sensitized alloy must have greater resistance to stress corrosion attacks and therefore the hardness must be smaller and the grain size smaller. To ensure that the alloys have the required grain size and hardness, the conditions during the mechanical processing and annealing must be controlled. The hardness and grain size depend both on the composition of the alloys and on the mechanical treatment and heat treatment to which they are subjected. High contents of titanium or aluminum thus lead to increased hardness. Aluminum, titanium and silicon must, however, be present in the minimum quantities listed above to ensure that the alloys are satisfactorily deoxidized and are heat-workable. However, in the presence of amounts greater than the stated maxima, stress corrosion cracking can occur when they are exposed to aerated high-purity water at elevated pressure and temperature. E.g. crack formation has taken place under these conditions in alloys containing 0.07% aluminum or 0.17% titanium or 0.44% silicon, but which are otherwise in accordance with the invention. The iron content of the alloys is advantageously no more than 25% and preferably no more than 10%. The highest resistance to stress corrosion cracking is exhibited by alloys containing from 14 to 25% chromium, 1 to 8% iron, 0.005 to 0.05% aluminum, 0.01 to 0.1% titanium, 0.01 to 0.25% silicon and 0.01 to 0.1% carbon, while the remainder, apart from impurities and residual deoxidizers, is nickel. ;Of the impurities usually present in nickel-chromium alloys, the amounts of sulfur and phosphorus shall be kept as low as possible in accordance with industrial practice and the amount of manganese shall not exceed 2% and preferably not amount to more than 1%. ;While the alloys can be annealed at any suitable temperature above the sensitization range, i.e. at least 815°C and up to 1150°C, high temperature annealing treatments, with or without the use of cold rolling, will result in coarse grain structures, particularly when the alloys are subsequently exposed for a sensitization treatment; in order to reduce the grain size to a minimum, it is therefore preferable that the alloys should not be annealed at temperatures above 930°C and the annealing is most advantageously carried out in the range of 840 to 900°C. At the low end of the temperature range, the alloys must be kept at the annealing temperature for approx. 1 to 2 hours or more, while at the high end of the temperature range, e.g. at 1095°C, they must be held at the annealing temperature for only a few minutes. A very satisfactory way of achieving a fine grain size is to cold roll the alloys to reduce the thickness by up to 50%, e.g. from 25 to 40%, and then anneal the alloys at 840 to 900°C. This treatment provides an ASTM grain size of No. 9 or less and is further advantageous in that higher amounts of carbon can be used, if this is desired, than would otherwise be the case. Cold rolling is advantageous because it leads to an elongated grain structure that is more resistant to intergranular attack. The best condition is a soft, elongated and fine-grained low-carbon alloy. As examples, alloys were produced with the compositions listed in Table I, in which alloys 1 to 7 are in accordance with the invention and alloys A to M are not in accordance with the invention. ; All the alloys were produced by vacuum melting from relatively high purity materials and they were cast as 4.5 kg ingots or ingots. After surface defects were removed, the blocks were forged and hot-rolled to form 5 mm thick plates which were then cold-rolled to a thickness of 3 mm and then cut into strips. Two strips of each alloy were then subjected to an annealing heat treatment consisting of solution heating at 1065°C for 15 minutes followed by water quenching and the high temperature of the solution treatment was purposely used to increase the toughness of the sample. Two additional strips of each alloy were subjected to a sensitizing heat treatment in which they were held at 700°C for 1 hour and air cooled. Each pair of strips was bent around a mandrel or mandrel to form U-shaped test pieces and the legs of the U-shaped test pieces were held parallel by means of a clamp. Before bending, each strip of each pair was ground to a depth of 0.13 mm over a length of 2.5 cm in the middle, so that a tapered depression or slot was formed in the strip after the bending. The test pieces were then subjected to stress corrosion tests whereby they were placed in autoclaves and immersed in a test solution consisting of high purity water that had been saturated with air at 1 atmosphere and adjusted to a pH of 10, and the autoclaves were filled with air in the space above the solution and heated to 315 to 350° Co. The tests were continued for a maximum of 8 weeks and the autoclaves were opened every 2 weeks and the test pieces were examined for cracks. When crack formation could not be observed with the naked eye, Isle the samples started again with fresh solution. The test pieces which did not show visible cracking at the end of 8 weeks were then examined metallographically. ;Table II shows the average hardness and grain size of each of the test pieces of each alloy in the annealed and sensitized condition, the time in weeks until visible cracking occurred and the results of the final metallographic examination where "C" means that cracks were formed. ; "-" shows that no cracks could be detected after 8 weeks. ; The results in Table II show that all the alloys A to M with compositions not in accordance with the invention show cracks as a result of the tests. The alloys H, I and K which. inside" contained too much titanium, exhibited high hardness and showed cracks even though they had a grain size of ASTM No. 8 or less. That low hardness values do not necessarily lead to resistance to stress corrosion cracking is evident from the results for alloys B, C and F. These alloys contained excessive amounts of aluminum (alloys B and C) and titanium (alloy F). and showed cracks although their annealed hardness did not exceed 148 VHN. The results for alloys A, D and L also showed that the presence of alum£fl.iw$/

titanium or silicon, in amounts as low as 0.07%, 0.17% and 0.44%,

led to crack formation although the relationship between hardness and grain size

can be reproduced at a point within the shaded area on the figure

ne 1 and 2. The results for alloy M show that when the relationship between hardness and grain size according to figures 1 and 2 is not satis-

set, cracking may occur even though the composition of the alloy

ning is within the range specified above.

In contrast to the alloys A to M, the alloys exhibit

nos. 1 to 7 satisfactory resistance to voltage

corrosion ion attack under the same test conditions. The compositions of each of the alloys Nos. 1 to 7 are in accordance with the invention and likewise also the relationship between the hardness and the grain size.

As a result of their low content of titanium and aluminum is

not the alloys according to the invention exposed to age-hardening

ning to a distinct degree.

The invention includes articles and parts which, when used, expose

are tested for high purity water at elevated temperatures and pressures and which are made from the annealed alloys.

Claims (4)

1. Annealed alloys with resistance equal to tension corrosion attack from aerated high-purity water under pressure at high temperatures, especially for use in nuclear reactors, character- enhanced by the fact that the alloys contain from 14 to 30% chromium, from 0 to 50% iron, from 0.003 to 0.05% aluminum, from 0.005 to 0.15_ % titanium, from 0.01 to 0.3% silicon and from 0.01 to 0.15% carbon, while the rest apart from pollutants and residual deoxidizing substances are nickel in an amount of at least 30%, and in which if the carbon content exceeds 0.03%, the grain size is presented and the hardness at a point within the shaded area of Figure 1 i attached drawing, and where the grain size and hardness will if doctor- the ring was heated to 700°C for 1 hour and air cooled, is represented of a point within the shaded area in Figure 2. 2. Alloy as specified in claim 1, characterized in that the iron content does not exceed 25%. 3. Alloy as stated in claim 1, characterized in that it contains from 14 to 25% chromium, 1 to 8% iron, 0.005 to 0.05% aluminum, 0.01 to 0.1% titanium, 0.01 to 0 .25% silicon and 0.01 to 0.1% carbon, while the rest apart from impurities and residual deoxidizing substances is nickel. 4. Alloy as specified in one of claims 1 to 3, characterized in that the carbon content does not exceed 0.03%.