A HYDROGEN EMBRITTLEMENT RESISTANCE COATED STEEL

Abstract

A method of production of a coated steel substrate including of the steps to have a steel substrate; performing electroplating of the steel substrate with an electroplating solution having a pH of from 2 to 6 and containing 100 g/l to 500 g/l of NiSO4 and 1 g/l to 15 g/l of MoS2, by applying a current density from 15 A/dm2 to 45 A/dm2 during 30 seconds to 300 seconds to generate a layer of Ni—MoS2 coating; thereafter, rinsing the steel substrate and drying it to obtain a coated steel substrate.

Description

The invention relates to a steel substrate having hydrogen embrittlement resistance and a method for manufacturing the same and particularly to a coated steel substrate having good resistance against Hydrogen embrittlement.

BACKGROUND

High strength steels such as dual phase (DP) steels, advanced high strength steels (AHSS), Ultra high strength steels (UHSS) or Martensitic Steel (MS) are characterized by having a high tensile strength. Because of these properties the use of such steels in the manufacture of automobiles has increased in response to the demands placed on the automotive industry to reduce the weight of motor vehicles without sacrificing passenger safety. This is so particularly for structural components such as a pillar, and reinforcing components such as a bumper and an impact beam, which are required to have a further increase in the strength thereof.

SUMMARY OF THE INVENTION

In addition, the all abovementioned steels to be used in automobiles are also required to be resistant to the occurrence of hydrogen induced delayed fracture which is commonly known as hydrogen embrittlement resistance steel. The hydrogen embrittlement generally refers to as the embrittlement caused by hydrogen generated during processing such electroplating, electrolytic cleaning or during application of end product in a corrosive environment or in atmosphere contents high moisture. This hydrogen diffuses into defective areas, such as dislocations, holes and grain boundaries, in the steel sheet, to embrittle the defective areas and cause deterioration in ductility and rigidity of the steel sheet, thereby causing fracture under that static or dynamic stress.

An object of the present invention is to solve these problems by making available a method and a coated steel substrate that is suitable to be used in automobile industry and that has an Hydrogen Embrittlement ratio of less than 30% and preferably less than 25% and more preferably less than 22%.

In a preferred embodiment, the steel substrate can have:

• • an ultimate tensile strength greater than or equal to 900 MPa and preferably above 980, and
  • a yield strength greater than or equal to 700 MPa and preferably above 800 Mpa.

Another object of the present invention is also to make available a method for the manufacturing of these substrates that is compatible with conventional industrial applications while being robust towards manufacturing parameters shifts.

The term “coated steel substrate” for the purpose of the present invention includes a hot rolled steel strip, cold rolled steel sheet, flat steel product, tailor welded blank, blank substrate containing one or more from C, Al, Si, and Mn as alloying elements and having a Ni—MoS2 layer thereon.

The present invention remedies the problem of Hydrogen Embrittlement by coating the steel with a layer of Ni—MoS2 having at least 0.3% of MoS2 particles by weight percentage with a thickness of the layer equal to or more than 0.1 micron.

The Ni—MoS2 layer of the present invention is able to withstand a welding process so that the Ni—MoS2 layer of the present invention can be welded for manufacturing of automobiles.

DETAILED DESCRIPTION

The method is specifically explained herein for the appreciation of the invention. The method can be according to the invention can be produced by the method consists of successive steps mentioned herein:

For the purpose of demonstration of the present invention martensitic steel is taken as a preferred embodiment steel which will be manufactured into a cold rolled steel sheet to demonstrate the beneficial effects of the present invention. The use of martensitic steel must not be considered as a limitation of the present invention and the method of the present invention can be implemented on any steel having any one or more, C, Mn, Al and Si as its alloying element.

A coated steel substrate according to the invention can be produced by any following method. A preferred method consists in providing a semi-finished casting of steel with a chemical composition of the according to the invention. The casting can be done either into ingots or continuously in form of thin slabs or thin strips, i.e. with a thickness ranging from approximately 220 mm for slabs up to several tens of millimeters for thin strip.

For example, a slab having the chemical composition of the steel is manufactured by continuous casting wherein the slab optionally underwent the direct soft reduction during the continuous casting process to avoid central segregation and to ensure a ratio of local Carbon to nominal Carbon kept below 1.10. The slab provided by continuous casting process can be used directly at a high temperature after the continuous casting or may be first cooled to room temperature and then reheated for hot rolling.

The temperature of the slab, which is subjected to hot rolling, is at least 1000° C. and at least 1280° C. It is preferred to have the temperature of the slab more than 1150° C., as below this temperature excessive load is imposed on a rolling mill and, further, the temperature of the steel may decrease to a Ferrite transformation temperature during finishing rolling, whereby the steel will be rolled in a state in which transformed Ferrite contained in the structure. Therefore, the temperature of the slab is preferably sufficiently high so that hot rolling can be completed in the temperature range of Ac3 to Ac3+100° C. and final rolling temperature remains above Ac3. Reheating at temperatures above 1280° C. must be avoided because they are industrially expensive.

A final rolling temperature range from Ac3 to Ac3+100° C. is preferred to have a structure that is favorable to recrystallization and rolling. It is necessary to have a final rolling pass to be performed at a temperature greater than 850° C., because below this temperature the steel sheet exhibits a significant drop in rollability. The sheet obtained in this manner is then cooled at a cooling rate above 30° C./s to the coiling temperature which below 650° C. Preferably, the cooling rate will be less than or equal to 200° C./s.

The hot rolled steel sheet is then coiled at a coiling temperature below 650° C. to avoid ovalization and preferably below 625° C. to avoid scale formation. The preferred range for such coiling temperature is from 400° C. to 625° C. The coiled hot rolled steel sheet is cooled down to room temperature before subjecting it to optional hot band annealing.

The hot rolled steel sheet may be subjected to an optional scale removal step to remove the scale formed during the hot rolling before optional hot band annealing. The hot rolled sheet may then have subjected to an optional Hot Band Annealing at temperatures from 400° C. to 750° C. for at least 12 hours and not more than 96 hours, the temperature remaining below 750° C. to avoid transforming partially the hot-rolled microstructure and, therefore, losing microstructure homogeneity. Thereafter, an optional scale removal step of this hot rolled steel sheet may performed through, for example, pickling of such sheet. This hot rolled steel sheet is subjected to cold rolling to obtain a cold rolled steel sheet with a thickness reduction from 35 to 90%. The cold rolled steel sheet is then obtained.

Thereafter the cold rolled steel is sent to a continuous annealing cycle for heat treatment which will impart the steel of the present invention with requisite properties and microstructure.

In annealing of the cold rolled steel sheet, the cold rolled steel sheet is heated at a heating rate which is greater than 2° C./s and preferably greater than 3° C./s, to a soaking temperature from Ac1 to Ac3+100° C. wherein Ac1 and Ac3 for the composite steel sheet is calculated by experimental dilatometer study.

The cold rolled steel sheet is held at the soaking temperature during 10 seconds to 500 seconds to ensure a complete recrystallization of the strongly work hardened initial structure. The cold rolled steel sheet is then cooled at a cooling rate greater than 5° C./s to a temperature less than 550° C. and preferably less than 500° C. The method further includes optionally holding the cold rolled steel sheet during 10 seconds to 1000 seconds from 150° C. to 500° C. to impart the requisite microstructure to the present invention, then cooling the cold rolled steel sheet to obtain the cold rolled steel substrate.

Then the cold rolled steel substrate is dipped in an acidic pickling solution during 5 seconds to 100 seconds at a temperature range from 30° C. to 100° C. to activate the surface for electroplating.

Ni—MoS2 layer is then deposited by electroplating on the surface of the cold rolled steel substrate to coat the substrate. Ni—MoS2 layer is made of a Nickel matrix in which the MoS2 particles are embedded. The MoS2 particles must be more than 0.3% by weight percentage of the total coated layer to impart the coated steel substrate with adequate hydrogen embrittlement resistance and preferably 0.4% or more and more preferably equal to or more than 0.5%. In a preferred embodiment, the presence of MoS2 may be restricted to 3% due to economic reasons.

Ni—MoS2 layer is electroplated onto the substrate by depositing an electroplate solution containing NiSO4 and MoS2 wherein the concentration of NiSO4 is from 100 g/l to 500 g/l and the concentration of MoS2 is from 1 g/l to 15 g/l to obtain a hydrogen embrittlement resistance on the cold rolled steel substrate. The concentration of the MoS2 is kept from 1 g/l to 15 g/l because the presence of MoS2 above 15 g/l in electroplating process decreases the efficiency of Ni deposition due to enhancement of hydrogen evolution reaction during electroplating. Concentration range of NiSO4 is optimized to obtain enough Ni deposition and embedding the MoS2 particles in the deposited Ni matrix during electroplating. The preferred concentration of the MoS2 is from 2 g/l to 14 g/l and more preferably from 3 g/l to 12 g/l. The preferred concentration of NiSO4 is from 100 g/l to 400 g/l and more preferably from 150 g/l to 400 g/l.

A current density from 15 A/dm² to 45 A/dm² is applied during 30 to 300 seconds during electroplating to embed the MoS2 particles with 0.3% or more by weight percentage in the nickel matrix of the Ni—MoS2 layer and to have thickness of at least 0.1 micron for Ni—MoS2 layer. It is preferable to have a layer thickness of more than 0.2 micron and more preferably more than 0.3 micron. If the current density is less than 15 A/dm² the MoS2 particles with 0.3% or more by weight percentage will not be embedded in the Ni-Matrix, thereby the final layer having Ni—MoS2 will not form. The temperature for electroplating the cold rolled steel substrate is usually maintained from 30° C. to 90° C. while the pH of the electroplating solution is maintained from 2 to 6. A preferred range for current density during electroplating from 15 A/dm² to 40 A/dm² and more preferably from A/dm² to 38 A/dm². The preferred time for electroplating is from 50 to 250 seconds and more preferably from 60 seconds to 200 seconds.

Thereafter, the cold rolled steel substrate is rinsed with any appropriate solvent, like ethanol for instance, and dried using, for example, hot air to obtain a coated steel substrate.

The coated steel substrate then may be optionally coated by any of the known industrial processes such as Electro-galvanization, JVD and PVD etc.

Then an optional post batch annealing may be done at a temperature from 150° C. to 300° C. during 30 minutes to 120 hours.

In a preferred embodiment, the chemical composition of the steel substrate to be used in the method according to the invention is as follows:

Carbon is present in from 0.05% to 0.5%. Carbon is an element necessary for increasing the strength of the Steel of the present invention by producing a low-temperature transformation phases such as Martensite, Bainite further Carbon also plays a pivotal role in Austenite stabilization, hence, it is a necessary element for securing Residual Austenite. Therefore, Carbon plays two pivotal roles, one is to increase the strength and another in Retaining Austenite to impart ductility. But Carbon content less than 0.05% will not be able to stabilize Austenite in an adequate amount required by the steel of the present invention. On the other hand, at a Carbon content exceeding 0.5%, the steel exhibits poor spot weldability, which limits its application for the automotive parts.

Manganese is present in the steel of the present invention from 0.2% to 5%. This element is gammagenous. The purpose of adding Manganese is essentially to obtain a structure that contains Austenite. Manganese is an element which stabilizes Austenite at room temperature to obtain Residual Austenite. An amount of at least about 0.2% by weight of Manganese is mandatory to provide the strength and hardenability to the Steel of the present invention as well as to stabilize Austenite. Thus, a higher percentage of Manganese is preferred by presented invention such as 2% or more. But when Manganese content is more than 5% it produces adverse effects such as it retards transformation of Austenite during cooling after annealing which retards he formation of other microstructural constituents. In addition, Manganese content of above 5% also deteriorates the weldability of the present steel as well as the ductility targets may not be achieved.

Silicon content of the steel of the present invention is from 0.1% to 2.5%. Silicon is a constituent that can retard the precipitation of carbides during overaging, therefore, due to the presence of Silicon Austenite is stabilized at room temperature. Further due to poor solubility of Silicon in carbide it effectively inhibits or retards the formation of carbides, hence, also promotes the formation of low density carbides in Bainitic structure which impart the Steel of the present invention with its essential mechanical properties such as tensile strength. However, disproportionate content of Silicon does not produce the mentioned effect and leads to problems such as temper embrittlement. Therefore, the concentration is controlled within an upper limit of 2.5%.

The content of the Aluminum is from 0.01% to 2%. In the present invention Aluminum removes Oxygen existing in molten steel to prevent Oxygen from forming a gas phase during solidification process. Aluminum also fixes Nitrogen in the steel to form Aluminum nitride so as to reduce the size of the grains. Higher content of Aluminum, above 2%, increases Ac3 point to a high temperature thereby lowering the productivity. Aluminum content from 0.8% to 1% can be used when high Manganese content is added in order to counterbalance the effect of Manganese on transformation points and Austenite formation evolution with temperature.

Sulfur is not an essential element but may be contained as an impurity in steel and from point of view of the present invention the Sulfur content is preferably as low as possible but is 0.09% or less from the viewpoint of manufacturing cost. Further if higher Sulfur is present in the steel it combines to form Sulfides especially with Manganese and reduces its beneficial impact on the present invention.

Phosphorus constituent of the Steel of the present invention is from 0.002% to 0.09%, Phosphorus reduces the spot weldability and the hot ductility, particularly due to its tendency to segregate at the grain boundaries or co-segregate with Manganese. For these reasons, its content is limited to 0.09% and preferably lower than 0.06%.

Nitrogen is limited to 0.09% in order to avoid ageing of material and to minimize the precipitation of Aluminum nitrides during solidification which are detrimental for mechanical properties of the steel.

Chromium content of the composite coil of steel of the present invention is from 0% to 1%. Chromium is an essential element that provide strength and hardening to the steel but when used above 1% impairs surface finish of steel. Further Chromium content under 1% coarsen the dispersion pattern of carbide in Bainitic structures, hence, keep the density of Carbide low in Bainite.

Nickel may be added as an optional element in an amount of 0% to 1% to increase the strength of the steel and to improve its toughness. A minimum of 0.01% is required to get such effects. However, when its content is above 1%, Nickel causes ductility deterioration.

Copper may be added as an optional element in an amount of 0% to 1% to increase the strength of the steel and to improve its corrosion resistance. A minimum of 0.01% is required to get such effects. However, when its content is above 1%, it can degrade the surface aspects.

Molybdenum is an optional element that constitutes 0% to 0.5% of the Steel of the present invention; Molybdenum plays an effective role in improving hardenability of the steel. However, the addition of Molybdenum excessively increases the cost of the addition of alloy elements, so that for economic reasons its content is limited to 0.4%.

Niobium is present in the Steel of the present invention from 0% to 0.1% and suitable for forming carbo-nitrides to impart strength of the Steel of the present invention by precipitation hardening. Niobium will also impact the size of microstructural components through its precipitation as carbo-nitrides and by retarding the recrystallization during heating process. Thus, finer microstructure formed at the end of the holding temperature and as a consequence after the complete annealing will lead to the hardening of the product. However, Niobium content above 0.1% is not economically interesting as a saturation effect of its influence is observed this means that additional amount of Niobium does not result in any strength improvement of the product.

Titanium is added to the Steel of the present invention from 0% to 0.1% same as Niobium, it is involved in carbo-nitrides so plays a role in hardening. But it is also forms Titanium-nitrides appearing during solidification of the cast product. The amount of Titanium is so limited to 0.1% to avoid the formation of coarse Titanium-nitrides detrimental for formability. In case the Titanium content is below 0.001% it does not impart any effect on the steel of present invention.

Calcium content in the steel of the present invention is from 0.001% to 0.005%. Calcium is added to steel of present invention as an optional element especially during the inclusion treatment. Calcium contributes towards the refining of the Steel by arresting the detrimental Sulfur content in globular form thereby retarding the harmful effect of Sulfur.

Vanadium is effective in enhancing the strength of steel by forming carbides or carbo-nitrides and the upper limit is 0.1% from economic points of view. Other elements such as Cerium, Boron, Magnesium or Zirconium can be added individually or in combination in the following proportions: Cerium ≤0.1%, Boron ≤0.003%, Magnesium ≤0.010% and Zirconium ≤0.010%. Up to the maximum content levels indicated, these elements make it possible to refine the grain during solidification. The remainder of the composition of the steel consists of iron and inevitable impurities resulting from processing.

The microstructure of the coated steel substrate may comprise any one or more than one from Residual austenite, martensite, tempered martensite, tempered bainite, ferrite and Bainite. Theses micro-constituents may comprise 90% or more of the microstructure of the coated steel substrate of the present invention. In addition to the above-mentioned microstructure, the microstructural components such as pearlite and cementite may also be present in the coated steel substrate but limited up to a maximum of 10% in total.

Examples

The following tests, examples, figurative exemplification and tables which are presented herein are non-restricting in nature and must be considered for purposes of illustration only and will display the advantageous features of the present invention.

Steel with different compositions is gathered in Table 1 which shows the two example steel compositions Steel A and Steel B, wherein the Table 2 shows parameters implemented for the coating NiMoS2. Thereafter Table 3 gathers the microstructures of the steel sheet obtained during the trials and table 4 gathers the result of evaluations of obtained for hydrogen embrittlement and mechanical properties.

TABLE 1
Samples	C	Mn	Si	Al	Cr	Nb	S	P	N	B	Ti
A	0.25	0.50	0.20	0.050	0.50	0.025	0.004	0.008	0.005	15 ppm	0.025
B	0.30	0.50	0.20	0.043	0.50	0.025	0.001	0.006	0.005	15 ppm	0.025

TABLE 2
				Current
Steel		NiSo4	MoS2	density		Temperature,	Time,
Samples	Trials	(g/l)	(g/l)	(A/dm2)	pH	° C.	sec
A	I1	300	5	20	3	50	180
A	I2	300	5	25	4	55	180
A	I3	300	8	30	5	45	180
B	I4	300	5	20	3	50	180
B	I5	300	5	25	4	55	180
B	I6	300	8	30	5	45	180
A	R1	300	5	10	4	60	180
A	R2	300	8	10	6	50	180
B	R3	300	5	10	4	60	180
B	R4	300	8	10	6	50	180
I = according to the invention; R = reference; underlined values: not according to the invention.

Table 2 gathers the coating parameters implemented on steels of table 1 to be coated on the steels to become a hydrogen embrittlement resistant steel. The Steel compositions 11 to 16 serve for the manufacture of hydrogen embrittlement resistant steel according to the invention. This table also specifies the reference steel which are designated in table from R1 to R4. Before coating the Steels both Inventive and reference steels were hot rolled with hot rolled finishing temperature of 890° C. and then coiled at 620° C. thereafter cod rolled with a reduction of 60%. The cold rolled steel is annealed at a temperature 880° C. and then cooled to room temperature to obtained annealed cold rolled steel sheet which is coated with a coating of NiMoS2 according to the conditions mentioned in table 2 to obtain a hydrogen embrittlement resistant steel.

The table 2 is as follows:

Table 3 exemplifies the results of the tests conducted for clearly elucidating the inventive feature of the method of the present invention, wherein key parameters of the NiMoS2 layers were determined by measuring with SEM cross section, the Concentration of MoS2 being measured by GDOES method. All trials microstructure was fully martensitic.

	TABLE 3
		Thickness of	MoS2
		electroplated	(wt %) in
	Trials	layer (μm)	Ni—MOS2
	I1	0.3	0.5
	I2	0.4	0.5
	I3	0.7	1.0
	I4	0.7	1.0
	I5	0.7	1.0
	I6	0.7	1.0
	R1	0.4	0
	R2	0.7	0
	R3	0.7	0
	R4	0.7	0
	I = according to the invention; R = reference; underlined values: not according to the invention.

Table 4 exemplifies the results of the tests conducted to demonstrate the mechanical properties and the hydrogen embrittlement resistance properties are measured in Hydrogen embrittlement ratio for the inventive and reference steels in accordance with method published in a journal publication titled as “Graphene coating as a protective barrier against hydrogen embrittlement” in the international journal of hydrogen energy of 39(2014) from page number 11810 to 11817. The results are stipulated herein:

		Hydrogen
		embrittlement ratio	TS	YS
	Trials	(% )	(MPa)	(MPa)
	I1	0	1621	1355
	I2	0	1650	1358
	I3	0	1660	1360
	I4	19	1795	1560
	I5	20	1808	1555
	I6	19	1787	1546
	R1	85	1370	1350
	R2	85	1350	1350
	R3	43	1790	1545
	R4	85	1570	1350
	I = according to the invention; R = reference; underlined values: not according to the invention.

Claims

1-12. (canceled)

13. A method of production of a coated steel substrate comprising the following steps: providing a steel substrate;electroplating the steel substrate with an electroplating solution having a pH of from 2 to 6 and containing 100 g/l to 500 g/l of NiSO4 and 1 g/l to 15 g/l of MoS2, by applying a current density from 15 A/dm2 to 45 A/dm2 during 30 seconds to 300 seconds to generate a layer of Ni—MoS2 coating;rinsing the electroplated steel substrate; anddrying the electroplated steel substrate to obtain a coated steel substrate.

14. The method as recited in claim 13 wherein the pH of the electroplating solution is from 2 to 5.

15. The method as recited in claim 13 wherein a concentration of NiSO4 in the electroplating solution is from 100 g/l to 400 g/l.

16. The method as recited in claim 13 wherein a concentration of MoS2 in the electroplating solution is from 2 g/l to 14 g/l.

17. The method as recited in claim 13 wherein the steel substrate submitted to the electroplating step is a cold rolled steel sheet obtained though the following steps: providing a semi-finished product of steel;reheating the semi-finished product to a temperature from 1000° C. to 1280° C.;rolling the semi-finished product in the austenitic range with a hot rolling finishing temperature above 850° C. to obtain a hot rolled steel sheet;cooling the sheet at an average cooling rate above 30° C./s to a coiling temperature below 650° C. and coiling the hot rolled steel sheet;cooling the hot rolled steel sheet to room temperature;optionally performing a scale removal step on the hot rolled steel sheet;optionally annealing the a hot rolled steel sheet at a temperature from 400° C. to 750° C.;optionally performing a further scale removal step on the hot rolled steel sheet;cold rolling the hot rolled steel sheet with a reduction rate from 35 to 90% to obtain a cold rolled steel sheet;then performing annealing by heating the cold rolled steel sheet at a rate heating rate greater than 2° C./s to a soaking temperature which is from Ac1 to Ac3+100° C. where the cold rolled steel sheet is held for 10 seconds to 500 seconds;then cooling the sheet at a rate greater than 5° C./s to a temperature below 550° C., wherein during the cooling the cold rolled steel sheet can optionally be held a temperature ranges from 150° C. to 500° C. for a time from 10 to 1000 seconds, to obtain a cold-rolled steel substrate; andthen acid pickling the cold rolled steel substrate is acid for 5 seconds to 100 seconds at a temperature range from 30° C. to 100°

18. A coated steel substrate manufactured according to the method as recited in claim 13, wherein the Ni—MoS2 layer has a thickness of at least 0.1 micron and contains at least 0.3% by weight percentage of MoS2 particles.

19. The coated steel substrate as recited in claim 18 wherein the Ni—MoS2 layer has a thickness of at least 0.2 micron.

20. The coated steel substrate as recited in claim 18 wherein the Ni—MoS2 layer contains at least 0.4% by weight percentage of MoS2 particles.

21. The coated steel substrate as recited in claim 18 wherein a hydrogen embrittlement ratio of the coated steel substrate is less than 30%.

22. The coated steel substrate as recited in claim 18 wherein the coated steel substrate is a cold rolled steel sheet with a composition comprising the following elements, expressed in percentage by weight: 0.05%≤C≤0.5%;0.2%≤Mn≤5%;0.1%≤Si≤2.5%;0.01%≤Al≤2%;0%≤S≤0.09%;0.002%≤P≤0.09%;0%≤N≤0.09%;and optionally one or more of the following elements:0%≤Cr≤1%;0%≤Ni≤1%;0%≤Cu≤1%;0%≤Mo≤0.5%;0%≤Nb≤0.1%;0%≤Ti≤0.1%;0%≤V≤0.1%;0%≤B≤0.003%;0%≤Mg≤0.010%;0%≤Zr≤0.010%;0.001%≤Ca≤0.005%;a remainder of the composition being composed of iron and unavoidable impurities caused by processing.

23. The coated steel substrate as recited in claim 18 wherein the steel substrate has an ultimate tensile strength of 900 MPa or more, and a yield strength of 700 MPa or more.

24. A method for manufacturing a structural part of a vehicle comprising the method as recited in claim 13.