The invention relates to the use of a nitrogen-alloyed nickel-chromium-iron alloy for a new application in the field of thermal recycling.
EP 2 632 628 A1 discloses a workable homogeneous austenitic nickel alloy having a high corrosion resistance against aggressive liquid media, both under oxidation and reducing conditions, and an excellent resistance against local corrosion in acid, chloride-containing media. The alloy consists of (in mass-%) chromium 26.0-28.0%, molybdenum 6.0-7.0%, iron max. 33.5%, manganese 1.0-4.0%, silicon max. 0.1%, boron 0.001-0.0040, copper 0.5-1.5%, aluminum 0.01-0.3%, magnesium 0.001 -0.15%, carbon max. 0.01%, nitrogen 0.1-0.25%, nickel 33.5-350, rare earths >0 to 1.0% and further smelting-related impurities. The alloy is suitable as a material for component parts that must be resistant to chemical attack.
As cladding materials for the build-up welding or the flame-spraying in the application for the thermal recycling, such as, for example, in refuse incineration systems, substitute material incineration systems or biomass systems, mostly nickel alloys are usually used at present, such as, for example, FM 625 (UNS N06625), FM 622 (UNS N06022) as well as FM 686 (UNS N06686).
Corrosion stresses in component parts and surfaces of thermal recycling systems contacted by flue gas are manifold and complex. Thus diverse diffusion-controlled high-temperature corrosion types occur, such as, for example, corrosion due to halogens containing chlorine and increasingly bromine, due to sulfidation, due to carburization, due to molten salts, or corrosion due to low-melting molten metals. Beyond this, the materials used are severely stressed additionally by wet-corrosion mechanisms during shutdown and maintenance periods in cases of dew-point undershoots or cleaning tasks. A further material stress occurs due to the thermal cycling load during startup and shutdown of the system or due to local and temporary “streaks of flame” in the incineration chamber.
Despite the corrosion protection of heat-exchanger tubes, heating surfaces as well as flue-gas-contacted surfaces and other component parts by cladding with these known materials, wasting away—depending on material used and operating conditions—takes place at the superheater tubes and other thermally stressed component parts, thus forcing the operator into shutdowns and cost-intensive maintenance work and possible necessary new construction.
The material described in EP 2 632 628 A1 has been used heretofore exclusively in the wet-corrosion area, in which electrochemical reactions in conjunction with electrolytes cause the corrosion attack. Known areas of application are: chemical processes involving phosphoric acid, sulfuric acid, seawater and brackish-water applications, or pickling systems using nitric acid/hydrofluoric acid.
A system for generation of energy from biomass has become known from DE 10 2007 062 810 A1. Parts of this system can consist of heat-resisting and corrosion-proof materials, preferably of stainless steel. Stainless steels with higher chromium and molybdenum contents are specified. The materials specified there are not suitable for build-up welding, however, since these relatively low-alloyed materials form residual delta ferrite to an increasing extent in the microstructure, especially in conjunction with the dilution by iron that takes place in the weld metal during build-up welding, thus greatly restricting the use in general both under wet and high-temperature corrosion conditions.
The objective of the invention is to provide the alloy that according to the prior art is permitted only for low temperatures up to max. 450° C. with a new field of application.
This objective is accomplished by the use of an alloy with the composition (in mass-%)
Ni 33.5-35.0%
Cr 26.0-28.0%
Mo 6.0-7.0%
Fe<33.5%
Mn 1.0-4.0%
Si≤0.1%
Cu 0.5-1.5%
Al 0.01%-0.3%
C≤0.01%
P≤0.015%
S≤0.01%
N 0.1-0.25%
B 0.001-0.004%
sE>0-1.0%
if necessary
W≤0.2%
Co≤0.5%
Nb≤0.2%
Ti≤0.1%,
as well as smelting related impurities,
as weld-cladding material in the field of thermal recycling systems, especially refuse, biomass, sewage sludge and substitute material incineration systems, wherein, after the build-up welding, the weld-cladding material selectively forms, in operationally-stressed condition, within a fully austenitic microstructure matrix, sigma phase and other hard particles in the weld-metal microstructure.
The formation of sigma phase causes a dispersion of hard particles in the weld-metal microstructure, which leads to an increase of hardness of the weld-metal microstructure, whereby an unexpectedly high resistance to the erosion-related depletion of protective top layers is achieved. Due to the formation of the sigma phase, a disproportional increase of the resistance of such a build-up weld is therefore achieved in thermal recycling systems in the operationally stressed condition. A further contribution against erosion or erosion-assisted corrosion is to be assumed due to the formation of chromium carbides at the application temperature. The weld metal therefore achieves an unusually high resistance against mechanical friction stress and thus also against erosion by particles and dust only in the operationally stressed condition, due to the precipitation of intermetallic phases such as the sigma phase.
It is also to be expected in the case of very long service times of more than 10,000 hours that, under the cyclic conditions of a thermal recycling system, where not only the purely diffusion-controlled/electrochemical corrosion plays a role, but in particular so also does the combination with the resistance of a material against mechanical stress, e.g. due to scattered and smoke particles (erosion and erosion-corrosion), this material acquires a novel properties profile.
In addition, the iron(II) chloride or iron(III) chloride formation that actually occurs in iron-containing materials, is strongly suppressed, with accompanying material dissolution, especially at low oxygen partial pressures.
In various laboratory investigations and welding activities under production conditions, it has been proved that this material acquires an excellent weldability—high safety against cracking and good wetting capacity—relative to the technique of weld cladding, both for the tungsten inert gas (TIG) welding technique and for the metal shield gas (MSG) welding technique. The application of weld-cladding layers may take place not only by build-up welding but also, for example, by flame or plasma spraying using powder or wire. Advantageously, the alloy is used together with the welding, flame spraying or plasma spraying techniques as cladding material in the field of systems for thermal recycling, such as, for example, refuse, biomass, sewage sludge, substitute material incineration systems.
In the wet corrosion test of ASTM G 48C, the critical pitting corrosion temperature for the parent metal in the delivery condition is typically higher than or equal to 85° C. The resistance to pitting corrosion is lowered by the formation of sigma phase, but nevertheless the alloy is so highly alloyed that the chromium contents present in the austenitic matrix ensure passivity.
Advantageous further developments of the subject matter of the invention can be inferred from the dependent claims.
The alloy is usable in particular for the coating of steels via the liquid phase, such as, for example, welding or flame spraying, which has a high corrosion resistance against aggressive media that may be formed during the thermal recycling.
Preferred chemical compositions (in mass-%) are listed in the following:
Ni 33.5-35.0%
Cr 26.0-28.0%
Mo 6.0-7.0%
Fe<33.5%
Mn 1.8-3.0%
Si≤0.1%
Cu 1.0-1.5%
Al 0.05%-0.3%
C≤0.01%
P≤0.015%
S≤0.01%
N 0.2-0.25%
B 0.001-0.004%
sE 0.020-0.060%
if necessary
W≤0.2%
Co≤0.5%
Nb≤0.1%
Ti≤0.5%,
as well as smelting related impurities.
During investigations of the above-mentioned material in the form of build-up welds on 16Mo3 tubes, it was surprisingly and unforeseeably found that this can also be used advantageously in the temperature range and under the specific conditions of thermal recycling.
In the following, the invention will be explained in more detail on the basis of an example:
In Table 1, the compositions are listed on the one hand for the build-up weld material according to the invention as well as for alternative materials used heretofore.
The material FM 31 plus as a weld-cladding material for component parts in thermal recycling systems is distinguished from the comparison materials by the autogenous development of property-improving microstructure phases in the range of the operating temperatures. Calculations with the J-MatPro software for Calphad in
Number | Date | Country | Kind |
---|---|---|---|
10 2020 109 510.4 | Apr 2020 | DE | national |
10 2021 106 624.7 | Mar 2021 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/DE2021/100280 | 3/22/2021 | WO |