Manufacturing process of hot press formed aluminized steel parts

What is claimed is: 1. A manufacturing process of a press hardened coated part comprising: providing a furnace (F) comprising N zones, N being not less than 2, each furnace zone 1, 2 . . . i, . . . , N being respectively heated at a setting temperature Θ 1F , Θ 2F , . . . Θ iF , Θ NF , implementing the following successive steps, in this order: providing at least one steel sheet with thickness th between 0.5 and 5 mm, the at least one steel sheet comprising a steel substrate covered by an aluminium alloy precoating with a thickness between 15 and 50 μm, the emissivity coefficient at room temperature of the at least one steel sheet being from 0.15 to 0.51, then cutting said at least one precoated steel sheet to obtain at least one precoated steel blank, then measuring the emissivity of said at least one precoated steel blank to determine the emissivity coefficient, the emissivity coefficient being equal to 0.15(1+α), then placing said at least one precoated steel blank in furnace zone 1 for a duration t 1 between 5 and 600 s, wherein Θ 1F and t 1 are such that: Θ 1Fmax >Θ 1F >Θ 1Fmin with: Θ 1Fmax =(598+ A e Bt1 +Ce Dt1 ) and Θ 1Fmin =(550+ A′e B′t1 +C′e D′t1 ) A, B, C, D, A′, B′, C′, D′ being such that: A=(762 e 0.071 th −426 e 0.86 th ) (1−0.345α), B=(−0.031 e −2.151 th −0.039 e −0.094 th ) (1+0.191α), C=(394 e 0.193 th −434.3 e −1.797 th ) (1−0.364α), D=(−0.029 e −2.677 th −0.011 e −0298 th ) (1+0.475α), A′=(625 e 0.123 th −476 e −1.593 th ) (1−0.345α), B′=(−0.059 e −2.109 th −0.039 e −0.091 th ) (1+0.191α), C′=(393 e 0.190 th −180 e −1.858 th ) (1−0.364α), D′=(−0.044 e −2.915 th −0.012 e −0.324 th ) (1+0.475α), wherein Θ 1F , Θ 1Fmax Θ 1Fmin are in ° Celsius, t 1 is in s., and th is in mm, and wherein the temperature of the at least one precoated steel blank at the exit of the furnace zone 1 is Θ 1B , then transferring said at least one precoated steel blank in said furnace zone 2 heated at a setting temperature Θ 2F =Θ 1B and maintaining isothermally the at least one precoated steel blank for a duration t 2 , Θ 2F and t 2 being such that: t 2min ≥t 2 ≥t 2max with: t 2min =0.95 t 2 * and t 2max =1.05 t 2 * with: t 2 *=t 1 2 (−0.0007 th 2 +0.0025 th− 0.0026)+33952−(55.52×Θ 2F ) wherein 02F is in ° Celsius, t 2 , t 2min , t 2max , t 2 * are in s., and th is in mm, then transferring said at least one precoated steel blank in further zones (3, . . . i, . . . , N) of the furnace, so to reach a maximum blank temperature Θ MB between 850° C. and 950° C., the average heating rate V a of the blank between Θ 2F and Θ MB being comprised between 5 and 500° C./s, then transferring the heated at least one precoated steel blank from the furnace into a press, then hot forming said heated at least one precoated steel blank in said press so as to obtain at least one part, then cooling said at least one part at a cooling rate in order to obtain a microstructure in said steel substrate comprising at least one constituent chosen among martensite or bainite. 2. A manufacturing process according to claim 1 , wherein the heating rate V a is between 50 and 100° C./s. 3. A manufacturing process according to claim 1 , wherein said precoating comprises, by weight, 5-11% Si, 2-4% Fe, optionally between 0.0015 and 0.0030% Ca, the remainder being aluminium and impurities inherent in processing. 4. A manufacturing process according to claim 1 , wherein said heating is performed by infrared heating. 5. A manufacturing process according to claim 1 , wherein said heating is performed by induction heating. 6. A manufacturing process according to claim 1 , wherein said at least one precoated steel blank has a thickness which is not constant and varies between th min , and th max , the ratio th max /th min being ≤1.5, and wherein said manufacturing process is implemented in said furnace zone 1 with Θ 1F and t 1 determined by th=th min , and implemented in said furnace zone 2 with Θ 2F and t 2 determined by th=th max . 7. A manufacturing process according to claim 1 , wherein after the maintaining of the at least one precoated steel blank in said furnace zone 2, and before transferring said at least one precoated steel blank in the further zones of the furnace, the at least one precoated steel blank is cooled down to room temperature, so to obtain a cooled at least one precoated steel blank. 8. A manufacturing process according to claim 7 , wherein the said cooled at least one precoated steel blank has a ratio Mn surf /Mn s between 0.33 and 0.60, Mn surf being the Mn content in weight % on the surface of said cooled at least one precoated steel blank, and Mn s being the Mn content in weight % of the steel substrate. 9. A manufacturing process according to claim 7 , wherein said heating rate V a is higher than 30° C./s. 10. A manufacturing process according to claim 9 , wherein said heating is obtained by resistance heating. 11. A manufacturing process according to claim 1 , wherein: a plurality of blanks batches having a thickness th are provided, wherein at least one (B 1 ) is a batch with α=α 1 and at least one is a batch (B 2 ) with α=α 2 , wherein α 1 ≠α 2 , said batch (B 1 ) is press hardened in process conditions (Θ 1F (α 1 ), t 1 (α 1 ), Θ 2 (α 1 ), t 2 (α 1 )) chosen according to claim 1 , then said batch (B 2 ) is press hardened in process conditions (Θ 1F (α 2 ), t 1 (α 2 ), Θ 2 (α 2 ), t 2 (α 2 )) chosen according to claim 1 , the temperatures and duration times in furnace zones (3, . . . i, . . . N) are identical for (B 1 ) and (B 2 ). 12. A manufacturing process according to claim 1 , wherein, after cutting said at least one precoated steel sheet and before placing said at least one precoated steel blank in said furnace zone 1, the emissivity of said precoated steel blank at room temperature is measured. 13. A manufacturing process according to claim 3 , wherein said precoating further comprises, by weight, between 0.0015 and 0.0030% Ca. 14. A manufacturing process according to claim 1 , wherein the press hardened coated part is a structural or a safety part of vehicles.