The rare earth metals constitute a group of 15 chemically related elements in group IIIB of the Periodic Table (lanthanide series). Their names are lanthanum, cerium, praseodymium, neodymium, promethium, samarium, europium, gadolinium, terbium, dysprosium, holmium, erbium, thulium, ytterbium and lutetium. The primary commercial form of mixed rare earth metals is so called misch metal, prepared by the electrolysis of fused rare earth chloride mixtures.

In general, it is well known that Fe-Cr-Al ferritic stainless steel is a material suitable for applications requiring high oxidation resistance, such as the catalyst substrate or carrier of an exhaust gas purifying device for automobiles.

US-A-5 578 265 discloses a ferritic stainless steel alloy which can be used as a catalytic substrate. The alloy consists essentially of (by weight): 19-21 % Cr; 4,5-6 % Al; 0,01-0,03 % Ce, with a total REM of 0,02-0,05 %, 20,015 % total Mg+Ca, and balance of Fe plus normally occurring impurities. The steel can be manufactured by producing a melt of the desired analysis, casting, hot rolling and cold rolling to thin sheets.

US-A-4 414 023 discloses an iron-chromium-aluminum alloy with a REM addition, which alloy is resistant to thermal cyclic oxidation and hot workable. According to this patent specification, a preferred aluminum content between 3 to 8 % is stated.

Further, it is stated that at aluminum contents above 8 %, there is a marked decline in the ability to texturize the aluminum oxide surface, i.e., to form alumina whiskers.

Previous works have claimed that foil production by conventional rolling methods is impossible at Al contents higher than 5-8% Al. The further addition of Al is said to be very detrimental to the ductility and toughness of the material. In US-A- 5 045 404 it is stated that when the Al content is more than 6,5%, not only the toughness

of a hot rolled strip is greatly lowered to thereby impair the processability, but also the - thermal expansion coefficient becomes extremely high and leads to a serious amount of thermal fatigue due to the repeated heating and cooling effects when used as a catalyst carrier.

US-A-5 228 932 describes a Fe-Cr-Al alloy having excellent oxidation resistance and high temperature brittleness resistance. The alloy consists of 10-28% Cr, l-l0%Al, additions of B, La and Zr and the balance Fe. At an Al content higher than 6%, it is stated that foil of this alloy can not be produced by conventional methods. In this case, an alternative manufacturing method is employed. Al is added to the surface of the alloy by sputtering, cladding, etc. After this, the foil is homogenized by a heat treatment.

In view of the above prior art, there has been a prejudice against increasing the Al concentration to levels above 8% by weight, although this is desirable due to improved oxidation resistance when higher Al contents are present. The main reason for this reluctancy of increasing the concentration of Al has resided in the assumption that an increase of the level of Al deteriorates the warm and cold workability such as warm and cold rolling to thin sheets. Therefore, the object to be solved by the present invention was to improve the oxidation resistance of ferritic stainless steel alloys while maintaining a good hot and cold workability, particularly in view of the use of the alloy as a catalyst carrier in the form of thin foils.

The present invention has managed to solve this problem by formulating a new class of ferritic stainless steel alloys according to claim 1 which can be successfully submitted to extensive warm and cold rolling in spite of a high Al content (> 8,0 % and < 12 % b.w. of aluminum).

Thus, the present invention provides a ferritic stainless steel alloy useful for strip steel used in exhaust gas catalytic converters, consisting of (in weight %): 15-21 % Cr; 8-12 % Al; 0,01-0,09 % Ce; 0,02-0,1 % total of REM; and possible minor amounts of further elements, other than the ones mentioned above,

the balance being Fe with normally occurring impurities, these impurities either partly coinciding with said possible minor amounts of further elements or being other elements than said possible minor amounts of further elements.

Said possible minor amounts of further elements may, e.g., be the following: <0,015%Ca; < 0,3% Ti (preferably 10,2 2%, most preferably <0,015 %); #0,5% Zr (preferably < 0,2 %, most preferably #0,1%); #0,5% Ni; #0,5% Mo; #0,3% V (preferably <0,1%); <0,3 % Nb (preferably < 0,1 %).

According to preferred embodiments of the invention, the alloy can contain: a total V, Ti, Nb and/or Zr of 0,05-1,0 %; 0,03-0,1 % V; 19-21 % Cr; 0,2-0,4 % Mn; and/or 0,1-0,4 % Si.

Further, the alloy according to the invention preferably contains 0,01 to 0,03 % by weight of Ce and 0,02 to 0,05 of REM. Again, it is noted that the Ce content is included in the REM content.

Depending on the raw materials used, a number of impurities may occur in the alloy according to the invention. For these impurities, the following maximal contents should suitably be observed: #0,02% C, preferably # 0,015%; <0,025 % Mg, preferably < 0,020 %, most preferably <0,015 %; <0,1 % N, preferably <0,025 % N, most preferably < 0,015 N; #0,02 % P; <0,005 % S;

<0,1 %W; <0,1 %Co; <0,1 %Cu; <0,1 %Sn.

The steel can be manufactured by producing a melt of the desired analysis, casting, hot rolling and cold rolling to thin sheets.

For illustrative but non limiting purposes, the invention will now be further described with reference to the appended drawing. Figure 1 shows the effect of aluminum content on the high temperature properties of Fe-Cr-Al alloys. The compositions of the alloys are according to the invention. The tests have been made on samples in the form of 1 mm thick sheet-metal.

The present invention provides a ferrite chromium aluminum strip steel useful for manufacture of monoliths for catalytic converters. The steel contains a higher aluminum content than conventional substrate materials in order to prolong the service life and raise the maximum service temperature of the catalytic converter. The steel also includes additives of REM which improve the adhesion of the surface oxide and consequently prevent scaling.

A metal-based monolith offers many advantages in comparison with a ceramic one. For instance, the metal-based monolith provides better thermal conductivity, shorter light-off time and less risk of overheating.

For this kind of application there is an advantage in using the material in the shape of a very thin foil, typically with a thickness of 20 to 50 ,um. The thickness of the foil is reduced to minimize the resistance for the exhaust gas flowing through the catalytic converter, but also to enhance the combustion efficiency. In order to enhance the efficiency of the combustion, work has been done to raise the service temperature of the catalytic converter. This has created a need for even more oxidation resistant substrate materials.

It is well known that the oxidation resistance of heat-resistant Fe-Cr-Al alloys is due to the formation of a compact, continuous layer of aluminum oxide, (a- Al203) on the surface of the alloy. The main factor for determining the lifetime of a

catalytic converter is the amount of Al in the material. During the use of the catalytic converter, the Al atoms in the substrate material migrate to the surface of the alloy by diffusion, to form aluminum oxide. This leads to a reduction of the Al content in the substrate material. The formation of a-Al203 proceeds to a point where the Al content in the substrate material is too low to form a-Al203. At this point, so called break-away oxidation occurs, by rapid oxidation of Fe and Cr. The formation of Fe and Cr oxides leads to spalling of the protective layer of a-Al203 and the oxidation accelerates even more.

The increase of the service temperature of the catalytic converter leads to accelerated oxidation kinetics. The Al atoms in the substrate material are consumed faster. This means a shorter service life for the catalytic converter.

The present invention has been developed in order to improve the oxidation resistance of the substrate material and thereby meet the demands for future catalytic converters. This is done by raising the Al content of the conventional alloy. The improvement of oxidation resistance is obtained together with an excellent warm and cold workability.

Oxidation properties of the steel according to the invention are shown in Fig 1. The percentages defined in Fig 1 refer to contents of Al. The diagram shows the weight gain as a function of the holding time at 1100°C. The diagram clearly demonstrates the positive effect of a higher Al content on the oxidation properties. As mentioned above, the tests were made on samples in the form of 1 mm thich sheet-metal.

As may be clearly seen in this diagram, the weight increase due to oxidation was considerably smaller for the two alloys according to the invention, i.e., the two ones with Al contents of 9,5 and 11,5 % b.w., respectively. The complete analyses of these two alloys correspond to heats No. 4 and 5, respectively, in Table 1. The "5,6" and "7,6" alloys in Fig 1 relate to heat No. 8 and 9, respectively, in Table 1. The lower weight increase, i.e., the lower Al consumption, together with the higher Al content, results in a longer service life of the catalytic converter.

The steel according to the invention can be manufactured by producing a melt of the desired analysis, casting, hot rolling and cold rolling to thin sheets. The composition preferably includes the weight percentages as defined above.

Examples of the of alloys in accordance with the invention are set forth in the following Table 1. According to the invention Prior art Heat No. 1 2 3 4 5 6 7 8 9 C 0,009 0,009 0,009 0,013 0,011 0,008 0,019 0,014 0,012 Si 0,11 0,1 0,07 0,18 0,17 0,07 0,34 0,2 0,18 Mn 0,09 0,09 0,07 0,21 0,21 0,08 0,32 0,27 0,21 P 0,008 0,009 0,008 0,015 0,013 0,009 0,009 0,015 0,012 S m 19 25 29 11 8 12 <10 7 9 Cr 20,83 19,98 20,81 20,5 20,4 21,53 20,33 20,8 20,7 Ni 0,15 0,13 0,14 0,23 0,23 0,14 0,32 0,27 0,23 Mo <0.01 <0.01 <0.01 0,01 0,01 <0.01 0,02 <0,01 0,01 Co 0,023 0,023 0,026 0,017 0,016 0,027 0,027 0,017 0,017 V 0,009 0,011 0,013 0,039 0,039 0,013 0,04 0,041 0,037 Ti 0,008 0,007 <0.005 <0,03 <0,03 <0.005 0,006 <0,005 <0,03 Cu - 0,031 - 0,015 0,015 - - 0,023 0,016 Al 8,9 8,5 8,8 9,5 11,5 6,3 5,2 5,6 7,6 Nb <0.01 <0.01 <0.01 <0,02 <0,02 <0.01 <0.01 <0,01 <0,02 Zr <0.005 <0.005 <0.005 <0,005 <0,005 <0.005 <0.005 <0,005 <0,005 N 0,009 0,019 0,025 0,0060,003 0,018 0,005 0,015 0,011 Ce 0,01 0,012 0,01 0,021 0,02 0,028 0,024 0,014 0,014 Mg 0,001 0,001 0,001 <0,001 <0,001 0,001 0,016 <0,001 <0,001 La - - - 0,011 0,011 - - 0,008 0,008