Stainless alloys for enhanced corrosion resistance

Abstract

An improved stainless alloy has application in handling concentrated sulfuric acid. The alloy of the invention preferably comprises 23 to 33% chromium, more than 20% nickel, 6% or more of silicon, 0.2% to 0.4% nitrogen and minor amounts of molybdenum, copper, and tungsten with the balance iron. The alloy offers superior corrosion resistance by comparison with the standard stainless steels over the range from 90% sulfuric acid into the oleum range. The alloy is readily weldable and may be used in either cast or wrought form. After heat treating the alloy acquires a duplex structure which has a mixture of austenite and ferrite phases. The heat-treated alloy is ductile.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

[0001] This application is a continuation of PCT international application No. PCT/CA99/00942 which designates the United States of America, is entitled STAINLESS ALLOYS FOR ENHANCED CORROSION RESISTANCE, and is hereby incorporated herein by reference.

FIELD OF THE INVENTION

[0002] This invention relates to alloys containing silicon, chromium, iron and nickel which have enhanced resistance to corrosion in acidic environments. The alloys of the invention have particular application in handling sulfuric acid over a wide range of concentrations.

BACKGROUND OF THE INVENTION

[0003] In many areas stainless steels and higher alloys have replaced cast irons as the materials of choice for handling sulfuric acid. In sulfuric acid plants which operate by the contact process, high volume circulating streams of sulfuric acid are used to dry process gases and absorb sulfur trioxide. In such plants, sulfuric acid contacts various pieces of process equipment including distributors, towers, pumps, valves, acid coolers and piping. Currently-available stainless steel compositions corrode much more quickly than is desirable for such applications, particularly under process conditions which involve high temperatures and/or high flow velocities.

[0004] Some alloys perform well in specific ranges of acid strength and/or temperature but none perform well under the full wide range of acid concentrations and temperatures that may be encountered in some chemical processes. Some cast iron materials offer reasonably good corrosion resistance properties. However, cast iron materials are brittle and can fail catastrophically. When better materials are available, the cost of such materials is often sufficiently high that thin walls must be used to keep costs down. The use of thin walls introduces risks of failure.

[0005] Keeping a sulfuric acid plant in safe operation requires continuous maintenance. Components which contact concentrated acids suffer undesirably premature corrosive degradation and must be periodically replaced. The operator of a sulfuric acid plant must keep up a program of continual inspection and replacement of acid-contacting components. This is true even when components are made with thick materials having heavy corrosion allowances. It is very expensive to replace corroded components in plants handling sulfuric acids. The components are often large and some are difficult to obtain.

[0006] It is now possible to operate sulfuric acid plants at higher efficiencies than were formerly possible by doing things such as using streams of acid as a heat recovery medium. These efficiencies are achieved at the expense of harsher process conditions, such as much higher acid temperatures. For example, the contact process for making sulfuric acid involves the absorption of sulfur trioxide in concentrated sulfuric acid. This reaction is highly exothermic and is typically performed in an absorbing tower. It was formerly considered necessary to maintain the acid in the absorbing tower at low temperatures to avoid rapid corrosion of acid-contacting components. This can make large acid flow rates necessary. A small increase in acid temperature can dramatically increase corrosion rates.

[0007] It has been realized that the heat generated by the absorption of sulfur trioxide may be used to heat feed water to make steam or to heat some other medium. Where heat is recovered from the acid exiting an absorbing tower it is desirable to maintain the acid temperature high to maximize the amount of energy which can be recovered from the hot acid. It is therefore desirable to allow the acid to reach temperatures higher than were previously considered prudent.

[0008] Further advantages can be obtained if acid handling components are able to withstand acid at higher temperatures. For example, if it is acceptable to allow higher acid temperatures then the flow rate of acid through some components, such as absorption towers, can be reduced. This can lead to savings in pumping, pipe, towers and heat exchangers and also provides greater freedom to design absorption towers.

[0009] Harsher process conditions accelerate corrosion and increase the potential harm caused by failed components. Most plants are operated under process conditions near limits imposed by the materials from which the components of process equipment are made. Such plants must be operated and maintained very carefully to avoid catastrophic equipment failures.

[0010] The standard stainless steels used for handling sulfuric acid are austenitic. A.I.S.I. 304, 316, 309, and 310 type stainless steel alloys are most common. In most cases these alloys can handle cooled product acid or strong acid having a concentration of about 98% without anodic protection as long as flow velocities, temperatures and turbulence are low. With anodic protection, these materials can be used in hotter acids and the ability to withstand turbulence is increased. Even with anodic protection, however, the use of such materials is normally restricted to solutions containing more than 93% sulfuric acid.

[0011] Many alternative materials have been suggested for use in the handling of concentrated sulfuric acids. However, all of these materials lack desirable features. For example, while some materials are more highly resistant to corrosion than conventional materials at certain acid concentrations they are more susceptible to corrosion at other acid concentrations. Many materials which are highly corrosion resistant are extremely brittle and therefore cannot be easily worked and may fail catastrophically. Some corrosion resistant materials are not weldable or can only be welded under stringent conditions. Many of these materials also lack versatility. Others are prohibitively expensive for use in most applications.

[0012] Jones et al., Canadian Patent No. 1,181,569 discloses that addition of a significant quantity of silicon (preferably about 5.3% silicon) to an austenitic stainless steel greatly improves corrosion resistance to 98% sulfuric acid and to tolerance of turbulence and high velocity. Stainless steel materials having the compositions described by Jones et al. are used widely in sulfuric acid plants in pump tanks, towers, acid piping, and distributors. A typical such material is designated A611 and has the composition Ni 17.5%, Cr 17.5%, Si 5.3%, C<0.015% with the balance being Fe. Unfortunately, while the compositions disclosed by Jones et al., including A611, are corrosion resistant at absorbing acid strength (98-99.5%), the compositions are heavily corroded in oleum or “fuming sulfuric acid” (which contains free liquid SO3). The compositions also exhibit accelerated corrosion rates at lower acid concentrations. At 50° C., (122° F.) A611 corrodes faster in 70% sulfuric acid than does conventional 316L stainless steel. Furthermore, the Jones et al. materials typically require anodic protection to achieve the lowest corrosion rates. It has also been found that the Jones et al. compositions must contain a number of trace elements and require special care in welding and fabrication. Jones et al. do not explain how to select trace elements to maintain the desired austenitic structure.

[0013] Culling, U.S. Pat. No. 5,306,464 suggests alloys having the formulation: Ni-15-25%, Si-4.5-8%, Cr-15-26%, Cu-1-4%, Mo 0.3-3% and the balance Fe. Culling '464 does not give any examples of alloys having more than 21.35% Cr. The alloys described in Culling '464 have high carbon contents in the range of 0.5 to 1.7% to produce an acceptable microstructure with acceptable mechanical properties. The high carbon content prevents Culling's alloy from being ductile. The maximum tensile elongation reported in Culling '464 is 4.7%. Culling determined that alloys with high silicon contents and low carbon contents tended to be even more brittle and to have other undesirable mechanical properties.

[0014] Culling, U.S. Pat. No. 4,836,985 discloses a nickel based alloy with very little iron and, therefore, a negligible tendency to form ferritic phases. Culling, U.S. Pat. No. 4,917,860 discloses alloys which have silicon contents of less than 4.5%.

[0015] U.K. Pat. No. 1,534,926 proposes a broad range of alloys said to be resistant to concentrated sulfuric acid but only provides examples of low-nickel stainless steel alloys.

[0016] Horn, U.S. Pat. Nos. 5,051,253 and 5,120,496 disclose alloys of 4-9% silicon with iron, chromium, and nickel. None of the examples given by Horn show both high silicon contents in excess of 6% and high chromium contents in excess of 22%. Horn provides no results of mechanical tests or corrosion resistance data for any materials having 6% or more silicon.

[0017] Sridar, U.S. Pat. No. 5,063,023 discloses a nickel-based alloy containing about 20% chromium, 2% copper, 2% iron, 2% molybdenum, 5% silicon and the balance nickel.

[0018] Despite over a century of research directed to identifying materials which can be used in equipment for handling industrial quantities of sulfuric acid there is still much room for improvement. The teachings of prior patents and other publications are sometimes contradictory and often do not provide data to support the full range of suggested compositions.

[0019] Currently available silicon stainless steels are relatively corrosion resistant in very strong acid but the corrosion resistance falls off rapidly as the acid strength drops below 95%. While there has been speculation that higher silicon content stainless steels might have more desirable corrosion resistance properties, until now nobody has succeeded in making such a stainless steel alloy which is workable. Those who have tried to make stainless steels with increased silicon contents have found that the materials become essentially unworkable at high silicon levels. High silicon materials such as DURIRON™ a cast iron material which contains a large amount of iron silicide and has a silicon content of 14%, are typically extremely brittle, sensitive to thermal shock and are not available in wrought form.

[0020] There is a need for materials capable of handling strong sulfuric acids, including oleum, which have better corrosion resistance than the alloys which are currently used. Such materials should have low corrosion rates under the worst conditions expected in sulfuric acid plants. Preferably such materials should retain corrosion resistance at high temperatures to allow the use of process conditions not feasible with present materials. There is a particular need for such materials that can be formed into components of required shapes at reasonable cost by a variety of industrial processes and which can be easily welded.

SUMMARY OF THE INVENTION

[0021] Surprisingly, the inventors have found that workable stainless steel compositions which include significant amounts of both silicon and chromium yield corrosion resistance significantly better than that of alloys having enhanced chromium content or enhanced silicon content alone. The prior art generally teaches that to increase corrosion resistance one should decrease chromium content, or at least hold the chromium content fixed, and thereby make room for extra silicon. Furthermore, the prior art generally teaches that increasing the silicon content of stainless steels or stainless alloys tends to yield materials that are very brittle and not workable.

[0022] The inventors have found that certain stainless steel alloys having in excess of 22% chromium and in excess of 6% silicon by weight have exceptional resistance to corrosion and erosion in concentrated sulfuric acids and are workable. The workability of these materials combined with their high degree of resistance to corrosion by concentrated sulfuric acids is completely unexpected as is the wide range of acid concentrations over which the materials are usable. Upon heat treatment, materials according to preferred embodiments of the invention exhibit a duplex microstructure consisting of a mixture of austenite and ferrite. To maintain this microstructure the materials of the invention preferably have a nickel content in excess of 19%.

[0023] The inventors have discovered that adding a modest amount of copper and/or molybdenum in the presence of some nitrogen further remarkably increases corrosion resistance to sulfuric acid having a concentration of 98% or lower. Also, adding small amounts of vanadium and/or tungsten was found to increase corrosion resistance in 98% to 100% sulfuric acid.

[0024] Accordingly, the invention provides a corrosion resistant stainless steel alloy comprising at least 22% by weight chromium and at least 6% by weight silicon.

[0025] Another aspect of the invention provides a corrosion resistant alloy comprising 22% to 36% by weight chromium, 6% to 10% by weight silicon (in some embodiments 6% to 8% silicon), substantially the balance nickel and iron. In some embodiments the nickel content is in the range of about 18% to about 32% by weight nickel.

[0026] In one preferred embodiment of the invention the alloy consists essentially of: 25% by weight chromium; 6.5% by weight silicon; 20% by weight nickel; and, 51.5% by weight iron. Upon suitable heat treatment, as described below, materials according to preferred embodiments of the invention become ductile and are readily welded and formed.

[0027] Another aspect of the invention provides a method for making a workable metallic alloy which is resistant to corrosion by sulfuric acid. The method comprises: alloying at least 22% chromium, at least 6% silicon, at least 20% nickel, up to 4% copper, and iron; and, heat treating the resulting alloy at a temperature sufficient to cause the alloy to become ductile and to have a duplex structure consisting of a mixture of ferrite and austenite. Preferably the heat treatment temperature is a temperature in the range of 1100° C. to 1200° C. (2012° F. to 2192° F.).

[0028] Further advantages and aspects of the invention are described below.

Brief Description of the Drawings

[0029] The invention is described in more detail below in conjunction with the accompanying drawings in which:

[0030] FIG. 1 is a curve relating elongation to heat treatment temperature for an alloy according to an embodiment of the invention;

[0031] FIG. 2 is a plot showing acid temperatures at which the corrosion rate is 5 mils per year as a function of concentration of sulfuric acid; and,

[0032] FIGS. 3A through 3D are respectively histograms which compare corrosion rates of alloys according to the invention to corrosion rates of some commercial stainless steel alloys under the following conditions: 90% sulfuric acid at 100° C. (212° F.); 98% sulfuric acid at 160° C. (320° F.); 105% sulfuric acid at 70° C. (158° F.); and, 105% sulfuric acid at 100° C. (212° F.).

DETAILED DESCRIPTION

[0033] Samples of several alloys designated A1 through A8 having the compositions set out in Table I were made and subjected to accelerated corrosion tests in concentrated H2SO4. Except where otherwise stated, all references to elemental compositions in this specification and the appended claims are to percentages by weight of the named element(s). For comparison purposes samples of 310 stainless steel, A611 stainless steel and 700Si stainless steel having the compositions set out in Table I were also subjected to identical accelerated corrosion tests. 1 TABLE I Nominal Composition of Alloys Tested (wt. %) Alloy Cr Si Ni Cu Mo Fe A1 24 6.5 19.5 0.19 0.30 balance A2 24 6.5 19.5 3.19 0.30 balance A3 24 6.5 19.5 0.19 4.30 balance A4 24 6.5 19.5 2.19 2.30 balance A5 24 6.5 24.5 3.19 0.30 balance A6 24 6.5 29.5 3.19 0.30 baiance A7 24 8.5 19.5 0.19 0.30 balance A8 24 10.5  19.5 0.19 0.30 balance 310 25 0.5 20   — — balance A611   17.5 5.3 17.5 — — balance 700Si  9 7   25   — — balance

[0034] Each alloy was tested by exposing a sample of the alloy for 7 days to agitated 90 wt. % H2SO4 at 100° C. (212° F.). Each alloy was also tested by exposing a sample of the alloy for 7 days to agitated 98 wt. % H2SO4 at 160° C. (320° F). Table II shows the measured corrosion rates for each tested alloy in each of these environments. 2 TABLE II Alloy Corrosion Rates in H2SO4 90 wt. % H2SO4 at 98 wt. % H2SO4 at Alloy 100° C. (mils/year) 160° C. (mils/year) A1 11 20 A2 0.61 13.6 A3 0.61 23.5 A4 0.7 26.8 A5 0.08 8.14 A6 0.58 3.56 A7 5.93 9.2 A8 0.64 0.46 310 278 1.5 A611 523 32.4 700Si 6,900 0.4

[0035] The results tabulated in Tables I and II show the following:

[0036] 1. For a constant chromium content of 24 wt. %, an increase in the silicon content from 0.5 to 6.5 very significantly decreased the corrosion rate in both environments. Further increase in the silicon content to 8.5% and 10.5% further decreases the corrosion rate in both 90% and 98% sulfuric acid.

[0037] 2. Simultaneously increasing both the chromium content from 17.5 wt. % to 24 wt. % and the silicon content from 5.3 wt. % to 6.5 wt. % significantly decreased the corrosion rate in both environments.

[0038] 3. For a constant silicon content of about 6.5 wt. %, an increase in the chromium content from 9 wt. % to 24 wt. % significantly decreases the corrosion rate in both environments.

[0039] 4. The 700Si material, which has a high silicon content combined with a reduced chromium content unexpectedly has a corrosion rate in 90% sulfuric acid greatly in excess of that of the other materials tested.

[0040] The inventors have also discovered that the addition to the alloys of the invention of vanadium and tungsten adds significantly to corrosion resistance in 98-100% sulfuric acid while the addition of copper, in amounts up to 4% or molybdenum in amounts of up to 6%, or mixtures of copper and molybdenum in amounts up to 6% (with copper not exceeding 4% ), dramatically reduces corrosion rates in sulfuric acid concentrations below 98%. The addition of some nitrogen is beneficial in such alloys. Mixtures of copper and molybdenum may provide better corrosion resistance to sulfuric acids having concentrations of less than 98% than either copper or molybdenum alone. If a mixture of copper and molybdenum is used then copper should make up less than 4% of the alloy.

[0041] The above results are surprising. Providing a quantity of more than 22% chromium in the presence of more than 6% silicon unexpectedly provides drastically improved corrosion resistance in the alloys of the invention without destroying the workability or weldability of the resulting alloys. Having a high chromium content in addition to a high silicon content can be seen to increase resistance to corrosion by weaker (<98%) sulfuric acid.

[0042] While both Horn, U.S. Pat. No. 5,120,496 and Culling, U.S. Pat. No. 5,306,464 suggest a wide range of alloys which includes some alloys having silicon contents in excess of 6% and chromium contents in excess of 22%, neither Horn nor Culling provide any examples of such alloys and neither Horn nor Culling suggest that such alloys might be both workable and have exceptional resistance to corrosion. Culling's alloys demonstrate good corrosion resistance but have a high carbon content and are not workable, as evidenced by tensile elongation values of less than 5%. Horn provides no corrosion data for silicon contents of 6.45% or more.

[0043] A stainless steel alloy according to this invention comprises at least 22% chromium and at least 6% silicon and preferably contains 0.5% to 6% copper and molybdenum. Preferably the alloy of the invention comprises:

[0044] a) chromium 22% to 33%;

[0045] b) silicon 6% to 10%, and most preferably 6% to 8%;

[0046] c) copper and/or molybdenum totalling 0.2% to 6% (preferably 0.5% to 6% ) with:

[0047] i) up to 4% copper; and,

[0048] ii) up to 6% molybdenum;

[0049] d) manganese 0%-3%;

[0050] e) nitrogen in the range of 0.1% to 0.5%; and,

[0051] f) the balance nickel and iron.

[0052] Preferably the alloy contains in excess of 18% nickel. More preferably the alloy contains at least 20% nickel. The alloy may contain, for example, 20% to 30%, or more nickel.

[0053] Preferably for alloys to be used in 98% -100% sulfuric acid the alloy contains 2% to 4% of one or both of tungsten and vanadium. Minor amounts of other elements may also be present.

[0054] It is thought that the ratio of silicon to chromium should be kept in the range of 0.25 to 0.36. For one range of alloys according to the invention the preferred relative amounts of silicon and chromium are expressed by the formula:

WSi=(0.33±0.06)×WCr

[0055] where WSi is the percentage of silicon and WCr is the percentage of chromium.

[0056] On casting the alloys of the invention have structure containing austenite and a eutectic phase. On heat treatment the alloys become ductile. After heat treatment, most alloys of the invention acquire a duplex microstructure which has a mixture of austenite and ferrite. Preferably the duplex structure should have about 24% to about 30% by volume ferrite and the balance austenite. The relative amounts of nickel and iron maybe varied to adjust the relative amounts of austenite and ferrite in the heat-treated material. Increasing iron content at the expense of nickel tends to increase the ferrite content of the heat-treated material at the expense of austenite content. Increasing nickel content at the expense of iron content tends to increase austenite content of the heat-treated material at the expense of ferrite content. Chromium and silicon are known to promote the formation of ferrite phases. It is therefore generally desirable to increase the amount of nickel relative to iron as the silicon and chromium content is increased in order to achieve a duplex structure containing a mixture of austenite and ferrite after heat treating. In preferred embodiments of the invention the ferrite and austenite phases have very similar elemental compositions. Preferably the ratios of the chromium contents of the ferritic and austenitic phases are 1±0.2, more preferably 1±0.15, and the silicon contents of the ferritic and austenitic phases are 1±0.07, more preferably 1±0.05.

[0057] A preferred stainless steel alloy according to the invention consists essentially of:

[0058] chromium 24-26%;

[0059] silicon 6.5-7.5%;

[0060] nickel in excess of 19%, for example, 19-32%;

[0061] copper 3%-3.5%,

[0062] molybdenum 2%-3%;

[0063] carbon less than 0.08%;

[0064] trace amounts of other elements such as aluminum, boron and/or cerium which may be chosen by those skilled in the art, as is known in the art, for functions such as controlling grain growth or scavenging oxygen; and,

[0065] iron the balance.

[0066] For use in 98% to 100% sulfuric acid the alloy may additionally contain tungsten 2%-4% and/or vanadium 2%-4%.

[0067] The alloy of the invention may be used in either cast or wrought form and has been found to be weldable in both cast and wrought forms.

EXAMPLE 1

[0068] An alloy designated A9 having a composition of, 24.7% Cr, 19.2% Ni, 6.0% Si, 0.12% Cu, 0.001% Mo, 0.7% Mn, 0.01% C, and 0.045% N was cast. The as-cast alloy had a microstructure consisting of an austenitic matrix with a eutectic phase occupying approximately 20% to 25% of the volume. The grains of eutectic phase material tended to be acicular. The as-cast alloy was quite brittle. Several samples of the A9 alloy were heat treated. Each sample was heated to a selected temperature for two hours and then quenched in water. Mechanical properties of the as-cast alloy and the heat-treated samples are set out in Table III. 3 TABLE III VARIATION IN MECHANICAL PROPERTIES OF A9 ALLOY WITH HEAT TREATMENT AT VARIOUS TEMPERATURES Ultimate Heat Ferrite Yield Tensile Charpy Treatment Content Magnetic Hardness Strength Strength Elongation Impact (° F.) (%) Response Rc (ksi) (ksi) (%) (ft lbs.) None  0   NO 21.3 51.9  84.0  2.0  1.5 1800  0   NO 26.6 63.2  80.7  1.2  1.5 1950  0   NO 22.3 60.5  83.9  1.9  2.0 2000 24.5 YES 2050 23.0 YES 15.6 57.0 113.5 45.0 45.3 2100 25.9 YES 16.0 58.6 114.2 52.1 58.3 2150 26.4 YES 14.6 58.3 113.2 48.2 59.0 2200 27.0 YES

[0069] It can be seen that heat treatment at temperatures in excess of about 2000° F. causes a distinct change in mechanical properties including an increase in tensile strength from approximately 80 ksi to in excess of 110 ksi, an increase in elongation from less than 2% to more than 40%, and an increase in impact strength from less than 3 ft lbs. to more than 45 ft. lbs.

[0070] In studying the microstructure of the heat-treated A9 alloy it was found that at a heat treatment temperature of 1950° F. (1065 C.) the eutectic phase was converted to an intermetallic. At a slightly higher heat treatment temperature of 2000° F. (1093 C.) the intermetallic phase begins to transform into a delta ferrite so that the alloy is a duplex alloy having a microstructure characterized by regions of ferrite and regions of austenite. As the heat treatment temperature is increased the ferrite content increases gradually to 27% at a heat treatment temperature of 2200° F. (1204C.). FIG. 1 is a curve relating elongation to heat treatment temperature which illustrates the marked increase in ductility obtained by heat treating at temperatures in excess of approximately 2000° F.

[0071] Table IV compares the mechanical properties of a sample of the A9 alloy heat treated at 2100° F. to the mechanical properties of some commercially available stainless steel alloys. 4 TABLE IV COMPARISON OF MECHANICAL PROPERTIES Yield Ultimate Strength Tensile Strength Elongation Ferrite Alloy (ksi) (ksi) (%) Content (%) A9 58.6   114.2   52.1 27  A611 51.5   99.3 65 0 SANDVIK ™ SX 32    98 30 0 CEI ™ X53390 55.9 126 38 <40  WEIR ™ S32760 80   110 25 18  304SS 25    70 40 0

[0072] While the inventors do not wish to be bound by any particular theory of operation it was observed that the elemental composition of austenitic phases and ferritic phases in the A9 alloy were very closely similar. The inventors believe that the even distribution of elements, particularly silicon and chromium, between the ferritic and austenitic phases promotes corrosion resistance and enhances weldability. Corrosion resistance in stainless steels is typically provided by a passive layer. Corrosion is known to occur where one phase within an alloy has a lower concentration of elements capable of forming a stable passive layer than other phases within the alloy. In duplex alloys according to the invention where the elemental composition of austenitic phases and ferritic phases is substantially the same there is no weak point for corrosive attack to occur.

[0073] It was found that the A9 alloy could be worked either hot or cold after heat treatment at 2100 ° F. Both the as-cast A9 alloy and the heat-treated A9 alloy could be welded with good results. For example, a joint in a section of as-cast pipe was MIG welded under argon shielding gas at 100 Amperes DC using FOX™ SZW 23 filler material. The welds were sectioned and micrographed. The welds were found to have good penetration and were free from any significant visible inclusions.

EXAMPLE 2

[0074] Alloys according to the invention were made by alloying 310 stainless steel with various amounts of silicon, molybdenum, copper, and vanadium. The resulting alloys were tested for corrosion resistance in various concentrations of sulfuric acid at various temperatures. Table V shows the compositions of several tested alloys which are identified by the designations E1 through E24. 5 TABLE V Nominal Composition of Alloys Tested (wt. %) Alloy Cr Si Mo Cu W V C Ni Fe. 310 24 0.5 0.31 0.19 0.048 19.5 balance E1 24 6.5 0.31 0.19 0.048 19.5 balance E2 24 6.5 2.3 0.19 0.048 19.5 balance E3 24 6.5 4.3 0.19 0.048 19.5 balance E4 24 6.5 0.31 2.19 0.048 19.5 balance ES 24 6.5 0.31 3.19 0.048 19.5 balance E6 24 6.5 0.31 4.19 0.048 19.5 balance E7 24 8.5 0.31 0.19 0.048 19.5 balance E8 24 10.5 0.31 0.19 0.048 19.5 balance E9 24 6.5 0.31 0.19 0.048 24.5 balance E10 24 6.5 0.31 3.19 0.048 24.5 balance E11 24 6.5 0.31 3.19 0.048 29.5 balance E12 27 6.5 0.31 0.19 0.048 19.5 balance E13 29 6.5 0.31 0.19 0.048 19.5 balance E14 24 6.6 0.31 0.19 4 0.048 19.5 balance E15 24 6.5 2.3 0.19 2 0.048 19.5 balance E16 24 6.5 2.3 2.19 0.048 19.5 balance E17 24 6.5 4.3 4.19 0.048 19.5 balance E18 24 6.5 0.31 0.19 2 0.048 19.5 balance E19 24 6.5 0.31 0.19 4 0.048 19.5 balance E20* 24 6.5 0.31 3.19 0.048 19.5 balance E21** 24 6.5 0.31 3.19 0.048 19.5 balance E22 32.75 6.3 1.49 0.54 0.012 31.4 balance E23 32.75 8.3 1.49 0.54 0.012 31.4 balance E24 32.75 8.3 1.49 0.54 0.012 31.4 balance *low nitrogen **high nitrogen

[0075] Tables VI and VII lists the corrosion rates of alloys E1 through E24 under various conditions. 6 TABLE VI CORROSION RATES OF TEST ALLOYS IN H2SO4 70% 90% 90% 98% 98% 98% 98.5% 99% 100° C. 100° C. 130° C. 160° C. 200° C. 250° C. 200° C. 250° C. Alloy (212° F.) (212° F.) (266° F.) (320° F.) (392° F.) (482° F.) (392° F.) (482° F.) E1 3460 9 132 17 6.2 9.3 8.4 E2 2000 1 96 23 5 13 6.2 E3 200 0.6 94 24 2.6 8.6 4.7 E4 1160 0.7 5 14 1.1 9.2 5.1 E5 0.6 14 11 11 7.9 6.6 E6 650 0.4 6 8.8 0.1 11 6.7 E7 5.9 9.2 0.6 4.9 2.3 3.9 E8 0.64 0.5 0.2 0.8 0.3 0.1 E9 3300 26 91 6.6 12 8.4 10 5.5 E10 50 0.08 8.1 23.5 17 6.4 E11 33 0.58 3.56 9.7 6.9 E12 48 13 7.3 14 5.9 E13 19 18 7.6 12 8.8 E14 26 22 10 11 4.5 E15 2070 29 18 7 7 6 E16 75 0.73 14.5 27 1.9 19 7.6 E17 1.1 22 E18 19.5 25 12 3 E19 30.5 12 6.3 3.6 E20 1.5 12 12 12 E21 0.95 13 12 12 E22 1180 5.8 77 13 12 7.2 E23 11 13 1.6 2.9 E24 0.65 0.07 5.4 1.1

[0076] Alloy E10 was exposed to various concentrations of sulfuric acid at various temperatures and the corrosion rate was measured. FIG. 2 is a plot showing the temperatures at which the corrosion rate is 5 mils per year as a function of acid concentration. The curve labelled A pertains to alloy E10 of table V. For comparison purposes, the curve labelled B is for A611 stainless steel alloy and, the curve labelled C is for SANDVIK™ SX stainless steel alloy. The curve labelled D is the boiling temperature of sulfuric acid at 1 atmosphere pressure. 7 TABLE VII CORROSION RATES OF TEST ALLOYS IN OLEUM 101% 105.12% 105% Alloy 160° C. (320° F.) 100° C. (212° F.) 70° C. (158° F.) E1 1.55 7.83 0.70 E2 2.81 8.95 1.42 E3 23.0 7.7 0.73 E4 2.1 13.0 0.68 E5 1.87 6.97 0.44 E6 1.99 25.5 1.73 E7 6.48 E8 105 E9 1.95 7.84 0.70 E10 2.06 7.5 E11 2.26 14.4 E12 2.05 9.4 E13 1.27 5.18 E14 5.99 E15 8.23 E16 5.72 10.0 1.18 E18 6.50 E19 6.04 7.68 E20 1.74 14.7 E21 1.48 14.1 E22 1.79 10.3 0.73

[0077] FIGS. 3A through 3D are histograms which compare the corrosion rate of alloys according to the invention to the corrosion rates of various commercially available alloys under the same conditions. FIG. 3A is for alloy E10 in 90% sulfuric acid at 100° C. (212° F.). FIG. 3B is for alloys E8 and E24 in 98% sulfuric acid at 160° C. (320° F.). FIG. 3C is for alloy E13 in 105% sulfuric acid at 100° C. (212° F.). FIG. 3D is for alloy E5 in 105% sulfuric acid at 70° C. (158° F.).

EXAMPLE 3

[0078] Table VIII lists other alloys according to various embodiments of the invention. 8 TABLE VIII Nominal Composition of Example Alloys (wt. %) Alloy Cr Si Mo Cu W V C Ni Fe. P1 22 6.5 0 3 0 0 <0.05 20 Bal. P2 22 6.5 6 0 0 0 <0.05 20 Bal. P3 22 6.5 0 0 4 0 <0.05 20 Bal. P4 22 6.5 0 0 0 4 <0.05 20 Bal. P5 28 7.5 0 3 0 0 <0.05 26 Bal. P6 28 7.5 4 2 0 0 <0.05 26 Bal. P7 28 7.5 0.5 0.5 2 2 <0.05 26 Bal. P8 33 9.5 0.5 0.5 2 2 <0.05 35 Bal. P9 33 9.5 0 0 0 0 <0.05 35 Bal. P10 33 7.5 0.5 3 0 0 <0.05 35 Bal. P11 25 6.9 0.5 3 0 0 <0.05 30 Bal P12 23 6.8 0 0 0 <0.05 24 Bal. P13 23 6.5 0 2.5 0 0 22 Bal.

Applications

[0079] The inventors consider that the alloys of this invention have particular application when used for acid contacting components in sulfuric acid plants. Such components include heat exchangers, pipes, absorption towers, pumps, and the like. The alloys have particular application in handling sulfuric acid having concentrations in the range of 85% sulfuric acid to 40% oleum in plants which use the contact process to manufacture sulfuric acids. The alloys are also especially useful in situations where they are used in contact with acid having a concentration in the range of 90% to 98% at temperatures in excess of 130° C. (266° F.). For example, the alloys may be used to make vessels for concentrating sulfuric acid by boiling off water at 180° C. (356° F.).

[0080] The alloys of this invention may also be formed into and used as an acid-contacting component in a heat exchanger wherein one surface of the component is in contact with concentrated sulfuric acid and another surface of the component is in contact with concentrated phosphoric acid.

[0081] As will be apparent to those skilled in the art in the light of the foregoing disclosure, many alterations and modifications are possible in the practice of this invention without departing from the spirit or scope thereof. Accordingly, the scope of the invention is to be construed in accordance with the substance defined by the following claims.

Claims

1. A weldable alloy comprising:

24% to 36% chromium;

6% to 10% silicon;

at least 18% nickel;

0.5% to 6% of an alloying element selected from the group consisting of copper, molybdenum, and a mixture of copper and molybdenum, the copper not exceeding 4%;

0.05 to 0.45% nitrogen; and

the balance comprising iron and incidental impurities,

the alloy being heat treated at a temperature in the range of 1100° C. to 1200° C. to produce a duplex microstructure consisting of a ferrite phase and a austenite phase, the ferrite phase being about 24% to 30% by volume, and the austenite phase being the balance, the alloy further having a tensile elongation in excess of 40%.

2. The alloy of claim 1 wherein the ratio of silicon to chromium is in the range of 0.25 to 0.36.

3. The alloy of claim 1 wherein the relative amounts of silicon and chromium are expressed by the formula:

WSi=(0.33±0.06)×WCr

where WSi is the percentage of silicon and WCr is the percentage of chromium.

4. The alloy of claim 1 wherein the ratio of the chromium content of the austenite phase and the chromium content of the ferrite phase is 1±0.2, and the ratio of the silicon content of the austenite phase and the silicon content of the ferrite phase is 1±0.07.

5. The alloy of claim 1 further comprising 2% to 4% tungsten.

6. The alloy of claim 1 further comprising 2% to 4% vanadium.

7. An acid contacting component in a plant for manufacturing concentrated sulfuric acid by the contact process, the component having an acid-contacting surface made from the alloy of any one of the above claims.

8. The use of the alloy of claim 1, as an acid-contacting component in a heat exchanger in a process for recovering heat from acid having a concentration in excess of 95% and temperature in excess of 130° C.

9. The use of the alloy of claim 1, as an acid-contacting component in a heat exchanger wherein one surface of the component is in contact with concentrated sulfuric acid and another face of the component is in contact with concentrated phosphoric acid.

10. A stainless steel alloy consisting essentially of:

24% to 36% chromium;

6% to 8% silicon;

18% to 32% nickel;

0.2% to 0.45% nitrogen;

2% to 4% copper;

and, optionally,

0% to 2% molybdenum, 2% to 4% tungsten, 2% to 4% vanadium and 0% to 0.05% carbon;

the balance comprising iron and incidental impurities.

11. An alloy comprising

22% to 36% chromium,

6% to 10% silicon,

0.5 to 6% of an alloying element selected from the group consisting of up to 4% copper, molybdenum, and a mixture of up to 4% copper and molybdenum;

0.05 to 0.45% nitrogen; and,

the balance iron and nickel.

12. The alloy of claim 11 comprising molybdenum in an amount of less than 5%.

13. The alloy of claim 11 comprising chromium in an amount greater than 23%.

14. The alloy of claim 13 wherein the relative amounts of silicon and chromium are expressed by the formula:

WSi=(0.33±0.06)×WCr

where WSi is the percentage of silicon and WCr is the percentage of chromium.

15. The alloy of claim 13 wherein the ratio of silicon to chromium is in the range of 0.25 to 0.35.

16. The alloy of claim 10 comprising approximately 6.6% silicon and approximately 23% chromium.

17. The alloy of claim 11 comprising 0.2% to 0.4% nitrogen.

18. The alloy of claim 11 comprising 2% to 4% tungsten.

19. The alloy of claim 11 comprising 2% to 4% vanadium.

20. The alloy of claim 11 comprising copper in an amount of less than 4%.

21. A stainless steel alloy consisting essentially of:

22% to 36% chromium;

6% to 8% silicon;

18% to 32% nickel;

0% to 4% copper; and,

the balance iron.

22. A method for making a workable metallic alloy which is resistant to corrosion by sulfuric acid, the method comprising:

a) alloying at least 22% chromium, at least 6% silicon, at least 20% nickel, up to 4% copper, and iron; and,

b) heat treating the resulting alloy at a temperature sufficient to cause the alloy to become ductile and to have a duplex structure consisting of a mixture of ferrite and austenite.

23. The method of claim 22 wherein the heat treating is performed at a temperature in the range of 1100° C. to 1200° C.

24. The method of claim 22 wherein, after heat treatment the alloy has a duplex microstructure characterized by 24% to 30% by volume ferrite and the balance austenite.

25. The alloy of claim 2 further comprising 2% to 4% tungsten.

26. The alloy of claim 3 further comprising 2% to 4% tungsten.

27. The alloy of claim 4 further comprising 2% to 4% tungsten.

28. The alloy of claim 2 further comprising 2% to 4% vanadium.

29. The alloy of claim 3 further comprising 2% to 4% vanadium.

30. The alloy of claim 4 further comprising 2% to 4% vanadium.

31. The alloy of claim 5 further comprising 2% to 4% vanadium.

32. The use of the alloy of claim 2 as an acid-contacting component in a heat exchanger in a process for recovering heat from acid having a concentration in excess of 95% and temperature in excess of 130° C.

33. The use of the alloy of claim 3 as an acid-contacting component in a heat exchanger in a process for recovering heat from acid having a concentration in excess of 95% and temperature in excess of 130° C.

34. The use of the alloy of claim 4 as an acid-contacting component in a heat exchanger in a process for recovering heat from acid having a concentration in excess of 95% and temperature in excess of 130° C.

35. The use of the alloy of claim 5 as an acid-contacting component in a heat exchanger in a process for recovering heat from acid having a concentration in excess of 95% and temperature in excess of 130° C.

36. The use of the alloy of claim 6 as an acid-contacting component in a heat exchanger in a process for recovering heat from acid having a concentration in excess of 95% and temperature in excess of 130° C.

37. The use of the alloy of claim 2 as an acid-contacting component in a heat exchanger wherein one surface of the component is in contact with concentrated sulfuric acid and another face of the component is in contact with concentrated phosphoric acid.

38. The use of the alloy of claim 3 as an acid-contacting component in a heat exchanger wherein one surface of the component is in contact with concentrated sulfuric acid and another face of the component is in contact with concentrated phosphoric acid.

39. The use of the alloy of claim 4 as an acid-contacting component in a heat exchanger wherein one surface of the component is in contact with concentrated sulfuric acid and another face of the component is in contact with concentrated phosphoric acid.

40. The use of the alloy of claim 5 as an acid-contacting component in a heat exchanger wherein one surface of the component is in contact with concentrated sulfuric acid and another face of the component is in contact with concentrated phosphoric acid.

41. The use of the alloy of claim 6 as an acid-contacting component in a heat exchanger wherein one surface of the component is in contact with concentrated sulfuric acid and another face of the component is in contact with concentrated phosphoric acid.

42. The alloy of claim 12 comprising chromium in an amount greater than 23%.

43. The alloy of claim 11 comprising approximately 6.6% silicon and approximately 23% chromium.

44. The method of claim 23 wherein, after heat treatment the alloy has a duplex microstructure characterized by 24% to 30% by volume ferrite and the balance austenite.