Heat treatment of high strength cold rolled steel strip

The invention claimed is: 1 . A method of heat treating a cold rolled steel strip, which method comprises the steps of: prior to step a), heating an uncoated cold rolled steel strip from a first temperature, wherein first temperature is room temperature, to a temperature T 1 in the range of 680-740° C. at a single constant heating rate V 1 of 15.0-25.0° C./s; and further heating the uncoated cold rolled steel strip from the temperature T 1 to a soaking temperature T 2 within a soaking temperature range of (Ac3−60° C.) to (Ac3+20° C.) at a heating rate V 2 of 0.5-4.0° C./s; a) soaking the uncoated cold rolled steel strip at the soaking temperature T 2 within the soaking temperature range of (Ac3−60° C.) to (Ac3+20° C.) for a soaking time t 2 of 1-100 seconds, thereby obtaining a cold rolled steel strip having an at least partially austenitic microstructure; b) cooling the uncoated soaked steel strip resulting from step a) to a temperature T 4 in the range of Bn-Ms, wherein acicular ferrite is formed during the cooling in a temperature range between Bs and Ms, wherein step b) comprises a substep of cooling the soaked steel strip from step a) to a temperature T 3 in the range of 750-550° C. at a cooling rate V 3 of 2.0° C./s to 15° C./s; and wherein step b) comprises a substep of cooling the soaked steel strip from a temperature T 3 , to T 4 at a cooling rate V 4 of 20.0-60.0° C./s; c) heat treating the uncoated cooled strip obtained in step b) in a range between the temperature Bn-(Ms+50) for a period of time t 5 of 40-120 seconds, by heating to increase temperature from T 4 to a temperature T 5 between T 4 and Bs; c1) optionally a coating step of coating the heat treated steel strip with a protective coating following the heat treating of step c), d) cooling the heat treated, optionally coated, steel strip to a temperature T 7 in the range of ((Ms−50) to Mf) at a cooling rate of V 7 of 5.0-10.0° C./s and further cooling the heat treated, optionally coated, steel strip to ambient temperature at a cooling rate of V 8 of 5.0-20.0° C./s; such that the heat treated, optionally coated, steel strip has a microstructure (in vol. %) comprising: polygonal ferrite (PF)+acicular ferrite (AF)+carbide-free higher bainitic ferrite (HBF): 25-55; polygonal ferrite (PF): 0-45; carbide-free lower bainitic ferrite (LBF): 30-65; retained austenite (RA): 5-20; fresh martensite (M): 0-20; wherein the steel strip has a composition (in mass %) comprising: C: 0.15-0.35; Mn: 1.50-3.00; Si: 0.50-2.00; Al: 0.01-1.50; P: less than 0.050; S: less than 0.020; N: less than 0.0080; wherein the sum (Si+Al) is ≥0.60; and optionally one or more elements selected from 0<Cr≤0.35; 0<Cu≤0.20; 0<Ni≤0.50; 0<Mo≤0.30; 0<Nb≤0.10; 0<V≤0.10; 0<Ti≤0.10; 0<B≤0.0030; 0<Ca≤0.0050; 0<REM≤0.0100, wherein REM is one or more rare earth metals; and the remainder being iron and inevitable impurities, wherein the steel strip resulting from step d) has Tensile strength (TS)≥850 MPa; and wherein the steel strip resulting from step d) has: Yield strength (YS)≥500 MPa; and Total elongation (TE)≥14%. 2 . The method according to claim 1 , wherein step a) comprises soaking a cold rolled steel strip within a temperature range of (Ac3−50° C.)-(Ac3+10° C.). 3 . The method according to claim 1 , wherein step b) comprises cooling the soaked steel strip from step a) to the temperature T 4 at a cooling rate sufficient to avoid pearlite formation. 4 . The method according to claim 1 , wherein the soaking temperature is (Ac3−50° C.)-(Ac3+10° C.). 5 . The method according to claim 1 , wherein step c) is performed at least partially by latent heat produced by the bainite transformation. 6 . The method according to claim 1 , comprising a further heat treatment step between steps c) and d) or if step c1) is present between steps c) and c1), wherein the uncoated steel strip resulting from step c) undergoes heating to a temperature T 6 in the range of Bs-Bn for a period of time t 6 . 7 . The method according to claim 1 , wherein the step c1) is performed and comprises a hot dip galvanizing treatment and comprises a further heat treatment step wherein the steel strip resulting from step c) undergoes heating to a temperature T 6 in the range of Bs-Bn for a period of time t 6 . 8 . The method according to claim 1 , wherein the step c1) is performed. 9 . The method according to claim 1 , wherein the microstructure comprises in vol. %: polygonal ferrite (PF)+acicular ferrite (AF)+carbide-free higher bainitic ferrite (HBF): 25-50; polygonal ferrite (PF): 10-40; carbide-free lower bainitic ferrite (LBF): 30-60; retained austenite (RA): 7-15; fresh martensite (M): 0-15; and/or wherein the C content in retained austenite (RA) is 0.90 wt. % or more. 10 . The method according to claim 1 , wherein carbide free bainitic ferrite is formed when the temperature in step b is in a range between Bs and Ms, wherein carbide free high bainitic ferrite is formed when the temperature in step b is in a range between Bs and Bn, wherein carbide free low bainitic ferrite is formed when the temperature in step b is in a range between Bn and Ms. 11 . The method according to claim 1 , wherein the heat treated, optionally coated, steel strip has: at least 11% PF. 12 . The method according to claim 1 , wherein the heat treated, optionally coated, steel strip has: 0.01-0.321% Al; at least 1.17% Si; and AF is present. 13 . A heat treated cold rolled steel strip made by the method of claim 1 and having a composition (in mass %) comprising C: 0.15-0.35; Mn: 1.50-3.00; Si: 0.50-2.00; Al: 0.01-1.50; P: less than 0.050; S: less than 0.020; N: less than 0.0080; wherein the sum (Si+Al) is ≥0.60; and optionally one or more elements selected from 0<Cr≤0.35; 0<Cu≤0.20; 0<Ni≤0.50; 0<Mo≤0.30; 0<Nb≤0.10; 0<V≤0.10; 0<Ti≤0.10; 0<B≤0.0030; 0<Ca≤0.0050; 0<REM≤0.0100, wherein REM is one or more rare earth metals; and the remainder being iron and inevitable impurities; and a microstructure (in vol. %) comprising polygonal ferrite (PF)+acicular ferrite (AF)+higher bainitic ferrite (HBF): 20-55; polygonal ferrite (PF): 0-45; lower bainitic ferrite (LBF): 20-65; retained austenite (RA): 5-20; fresh martensite (M): 0-20; wherein the steel strip resulting from step d) has Tensile strength (TS)≥850 MPa; and wherein the steel strip resulting from step d) has: Yield strength (YS)≥500 MPa; and Total elongation (TE)≥14%. 14 . A method of heat treating a cold rolled steel strip, which method comprises the steps of: prior to step a) heating an uncoated cold rolled steel strip from room temperature to a temperature T 1 in the range of 680-740° C. at a single constant heating rate V 1 of 15.0-25.0° C./s; and further heating the uncoated cold rolled steel strip from the temperature T 1 to a soaking temperature T 2 within a soaking temperature range of (Ac3−60° C.) to (Ac3+20° C.) at a heating rate V 2 of 0.5-4.0° C./s; a) soaking the uncoated cold rolled steel strip at the soaking temperature T 2 within the soaking temperature range of (Ac3−60° C.) to (Ac3+20° C.) for a soaking time t 2 of 1-100 seconds, thereby obtaining a cold rolled steel strip having an at least partially austenitic microstructure; b) cooling the uncoated soaked steel strip resulting from step a) to a temperature T 4 in the range of Bn-Ms, wherein acicular ferrite is formed during the cooling in a temperature range between Bs and Ms; wherein