HIGH-STRENGTH ELECTRIC RESISTANCE WELDED STEEL TUBE AND PRODUCTION METHOD THEREFOR

FIELD OF THE INVENTION

The present invention relates to high-strength electric resistance welded steel tubes suitable for use in crash members for automobiles such as door impact beams, cross members, and pillars, and, in particular, to a high-strength electric resistance welded steel tube having both excellent formability and shock absorption.

BACKGROUND OF THE INVENTION

In recent years, for the purposes of achieving enhanced safety of automobiles and in particular ensuring safety of occupants, shock absorbing members for absorbing impact energy upon collision are installed in automotive bodies. For example, a high-strength steel tube having a desired high strength and a martensitic structure induced by a quenching treatment has been applied to door impact beams, i.e., shock absorbing members, as described in Patent Literature 1.

Patent Literature 1 discloses a method for producing an electric resistance welded steel tube for machine structural use, the method including quenching a steel tube containing C: 0.15 to 0.22%, Mn: 1.5% or less, Si: 0.5% or less, Ti: 0.04% or less, B: 0.0003 to 0.0035%, N: 0.0080% or less and one or more selected from Ni: 0.5% or less, Cr: 0.5% or less, and Mo: 0.5% or less, wherein the electric resistance welded steel tube for machine structural use has a tensile strength of 120 kgf/mm²or more. According to the technology described in Patent Literature 1, a high-strength steel tube that has a tensile strength of 120 kgf/mm²or more and an excellent elongation of 10% or more, that can be used for reinforcing automobiles, and that can be applied to door impact bars (door impact beams) and center cores for bumpers can be obtained by performing a heat treatment once.

Steel sheets having a tensile strength of 120 kgf/mm²or more are also disclosed in Patent Documents 2 to 7 which disclose the technologies related to high-strength cold-rolled steel sheets that are used in automotive structural members and have a tensile strength of 900 MPa or more. These steel sheets all have a dual phase structure containing a ferrite phase and a martensite phase or a structure containing a bainite phase and a retained austenite phase in addition to these phases, and the upper limits of the area fractions of the bainite phase and the retained austenite phase are defined. According to these literatures, it is because of this structure that the steel sheets exhibit both formability and high strength.

PATENT LITERATURE

PTL 1: Japanese Unexamined Patent Application Publication No. 3-122219

PTL 2: Japanese Unexamined Patent Application Publication No. 2010-255094

PTL 3: Japanese Unexamined Patent Application Publication No. 2010-126787

PTL 4: Japanese Unexamined Patent Application Publication No. 2009-242816

PTL 5: Japanese Unexamined Patent Application Publication No. 2009-203550

PTL 6: Japanese Unexamined Patent Application Publication No. 2007-100114

PTL 7: Japanese Unexamined Patent Application Publication No. 2005-163055

SUMMARY OF THE INVENTION

The technology described in Patent Literature 1 does not present a serious problem in the cases where steel tubes are used straight without being subjected to any working, such as in the cases of door impact beams. However, steel tubes that are used in other automotive shock absorbing members such as cross members and pillars that require complicated forming to make various shapes are required to exhibit excellent formability in addition to the high strength.

The technologies described in Patent Literatures 2 to 5 have problems in that, because of the low cooling rate after holding of heat during annealing, precipitation of carbides occurs, the solute C content in the ferrite becomes insufficient, the strength increase (bake hardening value or BH value) caused by a prestrain-baking finishing treatment is small, and a BH value of 100 MPa or more is not reliably achieved.

The technology described in Patent Literature 6 does not consider the cooling rate from the holding of heat during annealing to the start of water quenching. For example, when the time taken up to the start of water quenching is long due to the layout of the production line and thus the cooling rate is low, the C content distribution proceeds between ferrite and austenite and thus the amount of the solute C remaining in the ferrite presumably contributing to the bake hardenability is insufficient. Thus, Patent Literature 6 does not describe or anticipate that the BH value of 100 MPa or more is ensured.

In the technology described in Patent Literature 7, the cooling rate during finish annealing is low, e.g., 550° C./min at maximum in Examples, and the elongation is only about 8%. The elongation is generally low and 11% at maximum. Accordingly, when a steel sheet produced by the technology described in Patent Literature 7 is formed into an electric resistance welded steel tube, the elongation will further decrease due to the processing strain applied during tube forming and the resulting steel tube does not reliably achieve an elongation of 10% or more.

Under these requirements, the present invention provides a high-strength electric resistance welded steel tube that has excellent formability and that can ensure excellent shock absorption suitable for use in automotive shock absorbing members and a method for producing the high-strength electric resistance welded steel tube.

Note that “high strength” refers to a tensile strength TS of 1180 MPa or more.

Moreover, “excellent formability” refers to an elongation El of 10% or more and preferably 12% or more in the tube axis direction and a yield ratio (=0.2% proof stress/tensile strength×100(%)) of less than 90% determined by a tensile test using a JIS No. 12 tensile test specimen (GL: 50 mm) defined by Japanese Industrial Standards (JIS). Furthermore, “excellent shock absorption” refers to the case in which the strength increase (bake hardening value or BH value), i.e., the difference between the 0.2% proof stress after heat-treating (baking finishing) a 2% prestrained tube at 170° C. for 10 minutes and the strength upon application of a 2% prestrain, is 100 MPa or more and the yield ratio in the tube axis direction is 90% or more. The BH value is defined in FIG. 2.

The inventors of the present application have conducted extensive studies to find ways to improve the formability of electric resistance welded steel tubes while maintaining the high strength. As a result, the inventors have found that an electric resistance welded tube having excellent formability can be produced by using, as a material for a steel tube, a steel sheet (cold-rolled steel sheet) having a ferrite-martensite dual phase structure, excellent formability, and a desired bake hardenability and employing a tube production method with which a tube can be formed without significantly degrading the excellent formability of the material for a steel tube. After this electric resistance welded tube is worked to have a desired component shape, a heat treatment (baking finishing) is performed to increase the strength so that the proof stress is improved and the resulting component can reliably achieve excellent shock absorption.

The present invention has been made based on the above-described findings and conducting further studies. The summary of the present invention according to exemplary embodiments is as follows:

(1) A high-strength electric resistance welded steel tube having a composition including, in terms of percent by mass, C: 0.05 to 0.20%, Si: 0.5 to 2.0%, Mn: 1.0 to 3.0%, P: 0.1% or less, S: 0.01% or less, Al: 0.01 to 0.1%, N: 0.005% or less, and the balance being Fe and unavoidable impurities, and a structure which is a dual phase structure including a ferrite phase and a martensite phase, with a volume ratio of the martensite phase being 20 to 60%, in which a tensile strength TS is 1180 MPa or more, an elongation El in a tube axis direction is 10% or more, and a yield ratio is less than 90%; and after application of a 2% prestrain and baking finishing that includes a heat treatment of 170° C.×10 min, a strength increase (BH value) is 100 MPa or more and a yield ratio is 90% or more.

(2) In the high-strength electric resistance welded steel tube of (1), the composition further includes, in terms of percent by mass, at least one selected from Cu: 1.0% or less, Ni: 1.0% or less, Cr: 0.5% or less, Mo: 0.5% or less, Nb: 0.05% or less, Ti: 0.05% or less, W: 0.05% or less, and B: 0.0050% or less.

(3) In the high-strength electric resistance welded steel tube of (1) or (2), the composition further includes, in terms of percent by mass, Ca: 0.0050% or less and/or REM: 0.0050% or less.

(4) A method for producing a high-strength electric resistance welded steel tube, the method including a hot rolling process of hot-rolling a steel into a hot-rolled sheet; a cold-rolling process of pickling the hot-rolled sheet and cold-rolling the pickled hot-rolled sheet to prepare a cold-rolled sheet; an annealing process of annealing the cold-rolled sheet into a cold-rolled annealed sheet so as to prepare a material for a steel tube; and a tube production process of continuously forming the material for a steel tube into a substantially cylindrical open tube and electric-resistance-welding the open tube to prepare an electric resistance welded tube. The steel has a composition including, in terms of percent by mass, C: 0.05 to 0.20%, Si: 0.5 to 2.0%, Mn: 1.0 to 3.0%, P: 0.1% or less, S: 0.01% or less, Al: 0.01 to 0.1%, N: 0.005% or less, and the balance being Fe and unavoidable impurities. In the hot-rolling process, the hot rolling is conducted at a finishing temperature equal to or higher than an Ar₃transformation point and at a coiling temperature of 500 to 700° C. to prepare the hot-rolled sheet. In the annealing process, after the cold-rolled sheet is heated to and soaked at a temperature in a two-phase temperature region ranging from an Ac₁transformation point to an Ac₃transformation point, the sheet is cooled at an average cooling rate (defined as “average cooling rate 1”) of 10° C./s or more to a temperature in the range of 600 to 750° C. and then rapidly cooled at an average cooling rate (defined as “average cooling rate 2”) of 500° C./s or more from the temperature in the range of 600 to 750° C. to room temperature, and then a tempering treatment that includes re-heating the sheet to a temperature in the range of 150 to 300° C. is performed so as to prepare a cold-rolled annealed sheet. The forming is performed by a roll forming method involving a cage roll method. The electric resistance welded tube has a tensile strength TS of 1180 MPa or more, an elongation El in a tube axis direction of 10% or more, and a yield ratio less than 90%, and exhibits, after application of a 2% prestrain and baking finishing that includes a heat treatment of 170° C.×10 min, a strength increase (BH value) of 100 MPa or more and a yield ratio of 90% or more.

(5) In the method for producing a high-strength electric resistance welded steel tube of (4), the composition further includes, in terms of percent by mass, at least one selected from Cu: 1.0% or less, Ni: 1.0% or less, Cr: 0.5% or less, Mo: 0.5% or less, Nb: 0.05% or less, Ti: 0.05% or less, W: 0.05% or less, and B: 0.0050% or less.

(6) In the method for producing a high-strength electric resistance welded steel tube in (4) or (5), the composition further includes, in terms of percent by mass, Ca: 0.0050% or less and/or REM: 0.0050% or less.

According to the present invention, a high-strength electric resistance welded steel tube that has excellent formability suitable for use in shock absorbing members of automotives and that can reliably achieve excellent shock absorption after being formed into an actual component shape can be produced at low cost and thus the present invention provides remarkable industrial advantages. Moreover, the high-strength electric resistance welded steel tube according to the present invention can be used not only in door impact beams but also in all types of automotive parts such as automotive shock absorbing components, e.g., cross members and pillars, that require formability, and automotive body parts.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram showing one example of a facility for producing an electric resistance welded tube, the facility employing a CBR roll forming method suitable for implementing an embodiment of the present invention.

FIG. 2 is a schematic diagram showing the definition of a strength increase (BH value) after baking finishing.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

The reasons for limitations on the composition of a high-strength electric resistance welded steel tube are first described. Hereinafter, mass % is simply denoted as % unless otherwise noted.

C: 0.05 to 0.20%

Carbon (C) strengthens the steel and the C content in the present invention should preferably be 0.05% or more to ensure a desired strength. When the C content exceeds 0.20%, the weldability is degraded. Thus, in the present invention, the C content is preferably limited to be in the range of 0.05 to 0.20% and more preferably in the range of 0.08 to 0.18%.

Si: 0.5 to 2.0%

Silicon (Si) serves as a deoxidizing agent, strengthens the steel by forming a solid solution, accelerates formation of ferrite, and is thus an important element for ensuring excellent formability. Silicon also causes solid solution strengthening of the ferrite phase to thereby suppress the martensite phase fraction and achieve a desired high strength. The Si content needs to be 0.5% or more in order to attain these effects. In contrast, when the Si content exceeds 2.0%, large amounts of silicon oxides occur in the steel sheet surface and the chemical conversion treatability is thereby degraded. Accordingly, in the present invention, the Si content is advantageously limited to be in the range of 0.5 to 2.0% and preferably in the range of 1.0 to 1.8%.

Mn: 1.0 to 3.0%

Manganese (Mn) improves hardenability, promotes formation of the martensite phase, and increases the strength of the steel. The Mn content of 1.0% is required in embodiments of the present invention in order to reliably achieve a desired strength. In contrast, when the Mn content exceeds 3.0%, segregation is accelerated, slab cracks tend to occur during casting, and the amount of the martensite phase increases excessively, thereby degrading the formability. Accordingly, the Mn content is limited to be in the range of 1.0 to 3.0% and preferably in the range of 1.5 to 2.5%.

P: 0.1% or less

Phosphorus (P) is an impurity in the present invention and the P content is preferably as low as possible to avoid adverse effects on formability. However, excessively decreasing the P content increases the refining cost. Accordingly, the P content is limited to 0.1% or less which does not substantially cause adverse effects. Preferably, the P content is 0.05% or less.

S: 0.01% or less

As with phosphorus (P), sulfur (S) is an impurity in the present invention and the S content is preferably as low as possible to avoid adverse effects on formability. However, excessively decreasing the S content increases the refining cost. Accordingly, the upper limit of the S content is set to 0.01% and preferably 0.005% or less.

Al: 0.01 to 0.1%

Aluminum (Al) serves as a deoxidizing agent and the Al content needs to be 0.01% or more in order to achieve this effect. When the Al content exceeds 0.1%, saturation occurs and the effect that corresponds to the content cannot be anticipated. Accordingly, the Al content is limited to be in the range of 0.01 to 0.1% and preferably in the range of 0.01 to 0.08%.

N: 0.005% or less

Nitrogen (N) strengthens the steel but decreases the formability and the content of nitrogen as an impurity is preferably decreased as much as possible. However, excessively decreasing the N content increases the refining cost. Accordingly, the N content is limited to 0.005% or less which does not have substantial adverse effect. Preferably, the N content is 0.004% or less.

While the components described heretofore are the basic components, at least one selected from Cu: 1.0% or less, Ni: 1.0% or less, Cr: 0.5% or less, Mo: 0.5% or less, Nb: 0.05% or less, Ti: 0.05% or less, W: 0.05% or less, and B: 0.0050% or less and/or at least one selected from Ca: 0.0050% or less and REM: 0.0050% or less may be contained in addition to the basic composition.

Copper (Cu), nickel (Ni), chromium (Cr), molybdenum (Mo), niobium (Nb), titanium (Ti), tungsten (W), and boron (B) all increase the strength of the steel and one or more of these elements can be selected as needed and added.

Cu: 1.0% or less

Copper (Cu) increases the strength of the steel and improves the corrosion resistance, and may be contained as needed. These effects can be achieved at a Cu content of 0.05% or more but the hot workability is degraded at a Cu content exceeding 1.0%. Accordingly, when copper is to be used, the Cu content is preferably limited to 1.0% or less and more preferably 0.08 to 0.5%.

Ni: 1.0% or less

Nickel (Ni) increases the strength of the steel and improves the corrosion resistance and may be contained as needed. These effects can be achieved at a Ni content of 0.05% or more. However, since nickel is an expensive element, incorporation of a large quantity of Ni exceeding 1.0% increases the cost of the raw material. Accordingly, when the nickel is to be used, the Ni content is preferably limited to 1.0% or less and more preferably 0.08 to 0.5%.

Cr: 0.5% or less

Chromium (Cr) improves the hardenability and thus increases the strength of the steel, and improves the corrosion resistance. Chromium may be contained as needed. These effects are achieved at a Cr content of 0.05% or more. However, the formability decreases at a Cr content exceeding 0.5%. Accordingly, when chromium is to be used, the Cr content is preferably limited to 0.5% or less and more preferably 0.05 to 0.4%

Mo: 0.5% or less

Molybdenum (Mo) improves the hardenability and increases the strength of the steel through precipitation strengthening, and may be contained as needed. These effects are achieved at a Mo content of 0.05% or more. However, the ductility decreases and the cost of raw material increases at a Mo content exceeding 0.5%. Accordingly, when molybdenum is to be used, the Mo content is preferably limited to 0.5% or less and more preferably 0.1 to 0.4%.

Nb: 0.05% or less

Niobium (Nb) reduces the size of crystal grains and increases the strength of the steel through precipitation strengthening, and may be contained as needed. Such effects are achieved at a Nb content of 0.005% or more but the ductility decreases at a Nb content exceeding 0.05%. Accordingly, when niobium is to be used, the Nb content is preferably limited to 0.05% or less and more preferably 0.008 to 0.03%.

Ti: 0.05% or less

Titanium (Ti) reduces the size of crystal grains and increases the strength of the steel through precipitation strengthening, and may be contained as needed. Such effects are achieved at a Ti content of 0.005% or more but the ductility decreases at a Ti content exceeding 0.05%. Accordingly, when titanium is to be used, the Ti content is preferably limited to 0.05% or less and more preferably 0.008 to 0.03%.

W: 0.05% or less

Tungsten (W) increases the strength of the steel through precipitation strengthening and may be contained as needed. Such an effect is achieved at a W content of 0.01% or more but the ductility decreases at a W content exceeding 0.05%. Accordingly, when tungsten is to be used, the W content is preferably limited to 0.05% or less and more preferably 0.01 to 0.03%.

B: 0.0050% or less

Boron (B) improves the hardenability, thereby helping adjust the martensite fraction to be within a particular range and increases the strength of the steel, and may be contained as needed. Such effects are achieved at a B content of 0.0005% or more. However, saturation occurs and effects corresponding to the content cannot be anticipated at a B content exceeding 0.0050%, which is economically disadvantageous. Accordingly, when boron is to be used, the B content is preferably limited to 0.0050% or less and more preferably 0.001 to 0.003%.

Ca: 0.0050% or less and/or REM: 0.0050% or less

Calcium (Ca) and a rare earth element (REM) improve the ductility through morphological control of sulfide-based inclusions and may be contained as needed. Such an effect is achieved at a Ca content and a REM content of 0.0020% or more. However, at a Ca content and a REM content exceeding 0.0050%, the amount of inclusions becomes excessively large and the cleanness of the steel is decreased. Accordingly, when calcium and the rare earth element are to be used, the Ca content and the REM content are both preferably limited to 0.0050% or less and more preferably 0.0020 to 0.0040%.

The balance other than the components described above is Fe and unavoidable impurities.

Next, the reasons for limitations on the structure of the steel tube of embodiments of the present invention are described.

A steel tube of the present invention preferably has a dual phase structure including 20 to 60% of a martensite phase in terms of volume ratio with the remainder being a ferrite phase. Because of this structure, a desired high strength, excellent formability, and excellent bake hardenability are all attained.

A desired high strength is not achieved at a martensite phase fraction less than 20 vol % because the ferrite phase is dominant in the structure. At a martensite phase fraction exceeding 60 vol %, the martensite phase becomes dominant and a desired formability may not be ensured. Accordingly, the martensite phase fraction in the structure is limited to be in the range of 20 to 60% in terms of a volume ratio and preferably 40 to 55% in terms of volume ratio.

Next, a preferable method for producing the steel tube of the present invention is described.

In the present invention, a steel is subjected to a hot-rolling process, a cold-rolling process, and an annealing process to form a material for a steel tube, and the material for a steel tube is subjected to a tube production process to form an electric resistance welded tube.

The method for producing the steel is not particularly limited. Preferably, a molten steel having the above-described composition is refined by a common refining method using a converter or the like and formed into a slab or the like by a continuous casting method or an ingoting-rolling method so as to form a steel.

The steel is subjected to a hot-rolling process through which the steel is hot-rolled into a hot-rolled sheet.

The steel may be reheated after cooling or, when the steel holds a particular quantity of heat, may be directly sent to be hot-rolled without reheating. When reheating is to be performed, the heating temperature is preferably 1000 to 1250° C. When the heating temperature during reheating is less than 1000° C., deformation resistance is high and the load imposed on a rolling machine is excessively large, thereby possibly making rolling difficult. In contrast, when the heating temperature exceeds 1250° C., the crystal grains become coarse and the ductility decreases significantly.

Hot rolling includes rough rolling and finish rolling. The conditions of the rough rolling are any as long as a sheet bar having particular dimension and shape is obtained. The finish rolling involves rolling at a finishing temperature equal to or higher than the Ar₃transformation point of a steel strip, i.e., the material to be rolled. After the finish rolling, the steel strip is coiled at a coiling temperature of 500 to 700° C.

When the finishing temperature is lower than the Ar₃transformation point, finishing rolling involves rolling at an (α+γ) two-phase region and the structure is a mixed grain structure in which significantly coarse crystal grains and fine crystal grains are mixed. Thus, when a cold-rolling process and an annealing process are performed thereafter, satisfactory formability may not be reliably obtained and rough surfaces occur as a result of working such as press forming and bending work. Accordingly, the finishing temperature of the hot-rolling is limited to a temperature equal to or higher than the Ar₃transformation point. At a coiling temperature less than 500° C., a hard phase is generated during cooling, the roll load increases during cold-rolling, and thus the productivity is decreased. When the coiling temperature is high exceeding 700° C., a non-transformed austenite transforms into pearlite and thus formability is decreased. Thus, the coiling temperature is limited to be in the range of 500 to 700° C. The coiling temperature is preferably 650° C. or less.

The hot rolled sheet obtained through the hot-rolling process is next subjected to a cold-rolling process of pickling the hot-rolled sheet and then cold-rolling the pickled sheet into a cold-rolled sheet. The conditions of the cold-rolling process such as reduction during cold rolling are not particularly defined.

The resulting cold-rolled sheet is subjected to an annealing process to form a cold-rolled annealed sheet.

The annealing process is crucial in the present invention in order to reliably achieve the desired formability and the desired bake hardenability (BH). The annealing process is preferably conducted in a continuous annealing line.

In the annealing process, after the cold-rolled sheet is heated to a temperature in a two-phase temperature range ranging from the Ac₁transformation point to the Ac₃transformation point and soaked thereat, the sheet is cooled (average cooling rate 1) at an average cooling rate of 10° C./sec or more to a temperature in the range of 600 to 750° C. and then rapidly cooled (average cooling rate 2) from the temperature in the range of 600 to 750° C. to room temperature at an average cooling rate of 500° C./s or more. The sheet is then subjected to a tempering treatment of reheating the sheet to a temperature in the range of 150 to 300° C. and thereby made into a cold-rolled annealed sheet. Note that in order to stably achieve the desired high strength and the bake hardenability, the cooling rate (average cooling rate 1) from the soaking temperature to the temperature at the start of rapid cooling is preferably 15° C./s or more and the average cooling rate (average cooling rate 2) in the rapid-cooling treatment is preferably 800° C./s or more, more preferably 1000° C./s or more, and most preferably 1100° C./s or more.

When the heating and soaking temperature is outside the two-phase temperature region ranging from the Ac₁transformation point to the Ac₃transformation point, a (ferrite+martensite) structure having a desired structural fraction cannot be reliably obtained in the subsequent rapid cooling. When the cooling rate (average cooling rate 1) from the heat holding temperature to the temperature at the start of rapid cooling is less than 10° C./s, distribution of the C content proceeds between ferrite and austenite, the amount of solute C in the ferrite presumably contributing to bake hardenability becomes small, and thus the desired bake hardenability is not obtained. When the temperature at the start of rapid cooling is outside the range of 750° C. to 600° C., a (ferrite+martensite) structure having a desired structural fraction cannot be obtained. When the temperature at the start of rapid cooling exceeds 750° C., the ductility decreases. When the temperature at the start of rapid cooling is less than 600° C., a desired high strength cannot be reliably obtained. The soaking time at the above-described temperature is preferably 30 s or longer.

When the cooling rate (average cooling rate 2) from the temperature in the range of 600 to 750° C. to room temperature is less than 500° C./s on average, the amount of transformed martensite is small, a (ferrite+martensite) structure having a desired structural fraction cannot be formed, a desired high strength cannot be reliably achieved, and a desired bake hardening value of 100 MPa or more is not obtained due to a small amount of solute C in the ferrite presumably contributing to the bake hardenability. The cooling rate in the rapid-cooling treatment is the average cooling rate from the temperature at the start of rapid cooling to 200° C.

The method of the rapid cooling treatment is not particularly limited but jet flow water is preferably used for cooling from the viewpoint of suppressing variation in the material in the steel sheet width direction and longitudinal direction.

In the annealing process of the present invention, a tempering treatment in which the sheet is reheated to a temperature in the range of 150 to 300° C. is preferably performed after the rapid cooling treatment so as to further improve the toughness. The toughness-improving effect is not anticipated at a tempering temperature less than 150° C.

The ductility decreases due to the low-temperature tempering brittleness at a reheating temperature exceeding 300° C. Accordingly, the temperature range for reheating is limited to 150 to 300° C.

The resulting cold-rolled annealed sheet may be subjected to skinpass rolling if needed. The rolling reduction of skinpass rolling is preferably 0.2% or more and 1.0% or less. At a rolling reduction of skinpass rolling less than 0.20, a shape-correcting effect is not obtained. At exceeding 1.0%, deterioration of elongation becomes significant.

The cold-rolled annealed sheet (cold-rolled annealed steel strip) that have gone through the processes described above is used as a material for a steel tube, and a tube production process is conducted on the material for a steel tube to produce an electric resistance welded steel tube. The tube production process involves continuously forming the material for a steel tube into a substantially cylindrical open tube and electric-resistance-welding the open tube to form an electric resistance welded tube.

In the present invention, forming in the tube production process is performed by a roll forming method involving a cage roll method. The roll forming method involving the cage roll method refers to a forming technique with which small rolls called cage rolls are arranged along the tube outer surface so as to form a tube smoothly. Among the roll forming method involving the cage roll method, the roll forming method employing a chance-free bulge roll (CBR) method is preferred. According to this method, the strain applied to the strip during forming can be minimized and deterioration of the properties of the material caused by work hardening can be suppressed.

An example of a production facility for producing electric resistance welded tubes employing a CBR roll forming method is shown in FIG. 1. According to the CBR roll forming method, two edges of a strip 1 is preliminarily formed with edge bend rolls 2, the central part of the strip is bend-worked by using center bend rolls 3 and cage rolls 4 so as to form an element tube having a vertically long oval figure, and four positions of the base tube in the tube circumferential direction are over-bent with fin pass rolls 5, followed by reducing so as to conduct stretch forming of the tube side portions and the bend and return forming of the over-bent portion to thereby make a round element tube (refer to Kawasaki Steel Giho Vol. 32 (2000), pp. 49 to 53). The CBR roll forming method is characterized in that the strain applied to the material (strip) is small and the variation in strain applied in the tube circumferential direction is small compared with a conventional breakdown (BD) method. While the round element tube obtained as such is being pressed with squeeze rolls 7, the butting edges are welded by welding means (high-frequency resistance welding) 6 so as to form an electric resistance welded tube 8.

A steel sheet (material for steel tubes) which is obtained by the production method described above and has high strength, excellent formability, and excellent bake hardenability is used to form a tube through the tube production process described above. Thus, the strain applied during the tube production can be minimized, the work hardening can be suppressed, and a high-strength electric resistance welded steel tube that has excellent formability and capable of ensuring excellent shock absorption after being processed into a component can be produced.

The resulting high-strength electric resistance welded steel tube has a tensile strength TS of 1180 MPa or more, an elongation El in the tube axial direction of 10% or more, and a yield ratio of less than 90%. After the steel tube is subjected to a 2% prestrain and a baking finishing treatment of heat-treating the prestrained steel tube at 170° C. for 10 minutes, the strength increase (BH value) is 100 MPa or more and the yield ratio is 90% or more.

When the elongation of the electric resistance welded tube in the tube axial direction is less than 10%, the formability of the tube is degraded and it becomes difficult to form a desired shape. Preferably, the elongation is 12% or more. When the yield ratio of the electric resistance welded tube exceeds 90%, the formability of the tube is degraded and it becomes difficult to form a desired shape. The yield ratio is preferably 85% or less.

When the BH value of the electric resistance welded tube after baking finishing is less than 100 MPa, the energy absorbed upon collision becomes small and the tube does not satisfy the requirements for shock absorbing members. Preferably, the BH value is 110 MPa or more. The tube production process employed in producing the electric resistance welded tube of the present invention can minimize the strain applied during the tube production and the variation in strain applied in the tube circumferential direction is also decreased. Thus, in the electric resistance welded tube of embodiments of the present invention, the variation in BH value among positions in the tube circumferential direction (i.e., the difference between the maximum value and the minimum value) is small and the BH values at the respective positions in the tube circumferential direction excluding the resistance welded portion are uniform and within the range of 100 to 130 MPa. When the yield ratio of the electric resistance welded tube is less than 90%, the electric resistance welded tube absorbs less energy upon collision and does not satisfy the requirements for shock absorbing members.

In the present invention, the heat treatment condition for baking finishing is preferably set to 170° C.×10 min. However, this condition is the minimum heat treatment condition for obtaining the strength increase (BH value) of 100 MPa or more after the baking finishing. The electric resistance welded tube of embodiments of the present invention will exhibit an strength increase (BH value) of 100 MPa or more after baking finishing under any other favorable conditions. As for the heat treatment conditions under which an strength increase (BH value) of 100 MPa or more is obtained after the baking finishing, a heating temperature in the range of 170 to 250° C. is preferably held for 10 to 30 minutes. When the heating temperature is less than 170° C., the solute C required to yield the desired strength increase diffuses into dislocations and does not sufficiently pin the dislocations. As a result, the desired strength increase (BH value) is not reliably achieved after the baking finishing. In contrast, when the temperature is excessively high exceeding 250° C., not only the productivity decreases, but also the tube may come to be heated in the blue brittleness range, possibly resulting in deterioration of the material.

When the holding time is as short as less than 10 minutes, the diffusion time is insufficient and the required amount of solute C cannot reach dislocations. Thus, the desired strength increase (BH value) cannot be reliably achieved after baking finishing. In contrast, when the holding time is longer than 30 minutes, the productivity is decreased. Preferably, the holding time is 25 minutes or shorter.

EXAMPLES

Molten steel samples indicated in Table 1 are refined in a converter and continuously casted into slabs (steels). These slabs (steels) are subjected to a hot-rolling process under conditions indicated in Table 2 to form hot-rolled sheets (thickness: 2.4 to 3.0 mm), followed by pickling. The hot-rolled sheets were subjected to a cold-rolling process of cold-rolling the sheets into cold-rolled sheets, and the cold-rolled sheets were subjected to an annealing process under conditions shown in Table 2 to form cold-rolled annealed sheets (thickness: 1.2 to 1.8 mm). As a result, materials for steel tubes were obtained. Test specimens were taken from the obtained materials for steel tubes and structural observation and a tensile test were carried out. The test methods were as follows.

Structural Observation

Test specimens for structural observation were taken from the materials for steel tubes. Sections of the test specimens taken in the rolling direction were polished, corroded with nital, and observed with a scanning electron microscope (2000× magnification). Photographs of 10 or more areas of observation were taken, the types of the structures such as ferrite and martensite were identified with an image analyzer, and the structural fractions (volume ratios) of the respective phases were calculated.

(2) Tensile Test

JIS No. 12 tensile test specimens (gauge length: 50 mm) were taken from the materials for steel tubes according to JIS Z 2201 so that the tensile direction matched the rolling direction. A tensile test was carried out according to JIS Z 2241 to determine the 0.2% proof stress YS (MPa), the tensile strength TS (MPa), and the elongation El (%). The yield ratio YR was calculated and the strength and formability were evaluated.

The results are shown in Table 3.

Each of the materials for steel tubes was formed by a CBR roll forming method into a substantially cylindrical open tube. While pressing the butting edges with squeeze rolls, the butting edges were electric resistance welded by high-frequency resistance welding. As a result, an electric resistance welded tube (48.6 mm in outer diameter and 1.2 to 1.8 mm in thickness) was obtained. Some of the steel tubes were formed by a BD forming method in the tube production process.

The resulting electric resistance welded tube was subjected to structural observation, tensile test, and baking finishing test to evaluate the structure, the tensile characteristics, and the bake hardenability. The test methods were as follows.

(1) Structural Observation

Test specimens for structural observation were taken from each steel tube. Sections of the specimens taken in the tube axial direction were polished, corroded with nital, and observed with a scanning electron microscope (2000× magnification). Photographs of 10 or more areas of observation were taken, the types of the structures such as ferrite and martensite were identified with an image analyzer, and the structural fractions (volume ratios) of the respective phases were calculated as averages of 10 or more areas of observation.

(2) Tensile Test

JIS No. 12 tensile test specimens (gauge length: 50 mm) were taken from the steel tubes according to JIS Z 2201 so that the tensile direction matched the tube axis direction, and a tensile test was conducted according to JIS Z 2241 to calculate the 0.2% proof stress YS (MPa), the tensile strength TS (MPa), and the elongation El (%). The yield ratio YR was calculated and the strength and formability were evaluated.

(3) Baking Finishing Test

JIS No. 12 tensile test specimens were taken from the steel tubes according to JIS Z 2201 so that the tensile direction matched the tube axis direction. A 2% tensile strain was applied as a prestrain and a heat treatment at 170° C. was conducted for 10 minutes to perform baking finishing. The tensile test specimens were taken at particular positions in the tube circumferential direction (eleven positions 30° spaced from each other in the circumferential direction while assuming the electric resistance welded portion to be 0°; the electric resistance welded portion was excluded).

A tensile test was conducted on the treated specimens. The 0.2% proof stress YS and the tensile strength TS after the baking finishing were determined and the yield ratio (=(YS/TS)×100(%)) after the baking finishing was calculated. The bake hardening value (BH value) was calculated as shown in FIG. 2 by determining the difference between the 0.2% proof stress after baking finishing and the strength after application of a 2% strain. The maximum value and the minimum value of the BH value were determined from among the positions in the circumferential direction. YS and TS are each an arithmetic mean of the values at the positions in the circumferential direction.

The results are shown in Table 4.

In all of examples of the present invention, an electric resistance welded tube that has a high strength, i.e., a tensile strength TS of 1180 MPa or more and excellent formability, i.e., an elongation El in the tube axial direction of 10% or more and a yield ratio (=(0.2% proof stress/tensile strength)×100(%)) in the tube axis direction of less than 90%, and exhibits excellent shock absorption, i.e., a BH value of 100 MPa or more and a yield ratio in the tube axis direction of 900 or more, after application of a prestrain of 2% or more and a heat treatment at 170° C.×10 min (baking finishing). In all of the examples of the present invention, the variation in BH value among the positions in the circumferential direction is small and the BH values fall within the range of 100 to 130 MPa.

In contrast, comparative examples outside the range of the present invention have an insufficient strength, low formability, or an insufficient BH value.

The influence of the baking finishing conditions was also studied.

JIS No. 12 tensile test specimens were taken from the steel tube No. 1 (Example of the present invention) shown in Table 2 according to JIS Z 2201 so that the tensile direction matched the tube axis direction. A 2% tensile strain was applied as a prestrain and a heat treatment was performed while varying the heating temperature and holding time within the ranges of 100 to 250° C. and 5 to 30 minutes to perform baking finishing. The tensile test specimens were taken at particular positions in the tube circumferential direction (eleven positions 30° spaced from each other in the circumferential direction while assuming the electric resistance welded portion to be 0°; the electric resistance welded portion is excluded). A tensile test was conducted on the bake-finished specimens. The 0.2% proof stress YS and the tensile strength TS after the baking finishing were determined and the yield ratio (=(YS/TS)×100(%)) after the baking finishing was calculated. The bake hardening value (BH value) was calculated as shown in FIG. 2 by determining the difference between the 0.2% proof stress after baking finishing and the strength after application of a 2% tensile strain. The maximum value and the minimum value of the BH value were determined from among the positions in the circumferential direction. YS and TS are each an arithmetic mean of the values at the positions in the circumferential direction. The results are shown in Table 5.

When the heating temperature of the heat treatment is less than 170° C., i.e., outside the range of the preferable baking finishing, a BH value of 100 MPa cannot be reliably achieved unless excessively long baking finishing is conducted without considering the decrease in productivity. The excessively long baking finishing refers to the baking finishing that takes more than 30 minutes. Even when the heating temperature is 170° C. or more, a BH value of 100 MPa or more is not always achieved if the holding time is 5 minutes, i.e., less than 10 minutes, and a desired BH value cannot be stably achieved.

REFERENCE SIGNS LIST

1 strip

2 edge bend roll

3 center bend roll

4 cage roll

5 fin pass roll

6 welding means

7 squeeze roll

8 electric resistance welded tube

9 cutter

10 open tube

TABLE 1

Steel
Chemical composition (mass %)

No.
C
Si
Mn
P
S
Al
N
Cu, Ni, Cr, Mo, Nb, Ti, W, B
Ca, REM
Reference

A
0.130
1.40
2.2
0.018
0.0013
0.034
0.0020
—
—
Example

B
0.100
1.40
2.4
0.018
0.0013
0.034
0.0020
—
—
Example

C
0.180
1.40
2.2
0.018
0.0013
0.034
0.0030
—
—
Example

D
0.140
0.80
2.3
0.018
0.0013
0.034
0.0020
—
—
Example

E
0.130
1.40
2.2
0.018
0.0013
0.034
0.0020
Ti: 0.015, Nb: 0.021
—
Example

F
0.130
1.40
2.2
0.018
0.0013
0.034
0.0040
Cr: 0.15, Mo: 0.10
—
Example

G
0.130
1.40
2.2
0.018
0.0013
0.034
0.0020
V: 0.11
—
Example

H
0.130
1.40
2.2
0.018
0.0013
0.034
0.0020
Ni: 0.10, Cu: 0.10, B: 0.0015
—
Example

I
0.130
1.40
2.2
0.018
0.0013
0.034
0.0020
W: 0.10
Ca: 0.0030
Example

J
0.103
1.40
2.2
0.018
0.0013
0.034
0.0020
—
REM: 0.0030
Example

K

0.040

1.40
2.2
0.018
0.0013
0.034
0.0020
—
—
Comparative

Example

L

0.250

1.40
2.2
0.018
0.0013
0.034
0.0020
—
—
Comparative

Example

M

0.120

0.40

2.2
0.018
0.0013
0.034
0.0020
—
—
Comparative

Example

N

0.120

2.10

2.2
0.018
0.0013
0.034
0.0020
—
—
Comparative

Example

O

0.120
1.40

0.5

0.018
0.0013
0.034
0.0020
—
—
Comparative

Example

P

0.120
1.40

3.1

0.018
0.0013
0.034
0.0020
—
—
Comparative

Example

Q
0.130
1.40
2.2
0.018
0.0013
0.034
0.0020
—
Ca: 0.0025
Example

R
0.135
1.40
2.2
0.0009
0.0010
0.048
0.0030
—
—
Example

S
0.145
1.43
2.1
0.015
0.0009
0.035
0.0038
Ti: 0.015
—
Example

TABLE 2

Hot-rolling process

Steel

Heating
Finishing
Coiling

Cold-rolling process

tube
Steel
Transformation point (° C.)
temperature
temperature
temperature
Thickness
Reduction
Thickness

No.
No.
Ac₁
Ac₃
Ar₃
(° C.)
(° C.)
(° C.)
(mm)
(%)
(mm)

1
A
740
899
859
1200
900
700
3.0
40
1.8

2
B
738
908
868
1200
900
700
3.0
40
1.8

3
C
740
886
846
1200
900
700
3.0
40
1.8

4
D
722
870
830
1200
900
700
3.0
40
1.8

5
E
740
899
859
1200
900
700
3.0
40
1.8

6
F
743
903
863
1200
900
700
3.0
40
1.8

7
G
740
899
859
1200
900
700
3.0
40
1.8

8
H
739
898
858
1200
900
700
3.0
40
1.8

9
I
741
901
861
1200
900
700
3.0
40
1.8

10
J
740
899
859
1200
900
700
3.0
40
1.8

11

K

740
932
892
1200
900
700
3.0
40
1.8

12

L

740
871
831
1200
900
700
3.0
40
1.8

13

M

711
858
818
1200
900
700
3.0
40
1.8

14

N

761
934
894
1200
900
700
3.0
40
1.8

15

O

758
902
862
1200
900
700
3.0
40
1.8

16

P

731
902
862
1200
900
700
3.0
40
1.8

17
A
740
899
859
1200
900
700
3.0
40
1.8

18
B
738
908
868
1200
900
700
3.0
40
1.8

19
C
740
886
846
1200
900
700
3.0
40
1.8

20
Q
740
899
859
1200
900
700
3.0
40
1.8

21
R
740
898
858
1200
900
700
2.4
50
1.2

22
S
742
897
857
1250
910
580
3.6
50
1.8

23
A
740
899
859
1200
900
560
3
40
1.8

24
A
740
899
859
1200
900
600
3
40
1.8

25
A
740
899
859
1200
900
650
3
40
1.8

Annealing process
Tube
Tube

Heating and cooling conditions
Tempering
produc-
size

Aver-
Quenching
Aver-
Cooling
treatment
tion
(mm)

Heating
Hold-
age
start
age
stop
Heating
process
Outer

Steel

temper-
ing
cooling
temper-
cooling
temper-
temper-
Roll
diam-

tube
Steel
ature
time
rate 1
ature
rate 2
ature
ature
forming
eter

No.
No.
(° C.)
(s)
(° C./s)
(° C.)
(° C./s)
(° C.)
(° C.)
method
(mm φ)
Reference

1
A
860
500
11
680
1000
RT
200
C B R
48.6
Example

2
B
860
500
12
680
1000
RT
200
C B R
48.6
Example

3
C
860
500
15
680
1000
RT
200
C B R
48.6
Example

4
D
860
500
15
680
1000
RT
200
C B R
48.6
Example

5
E
860
500
19
680
1000
RT
200
C B R
48.6
Example

6
F
860
500
19
680
1000
RT
200
C B R
48.6
Example

7
G
860
500
15
680
1000
RT
200
C B R
48.6
Example

8
H
860
500
15
680
1000
RT
200
C B R
48.6
Example

9
I
860
500
10
680
1000
RT
200
C B R
48.6
Example

10
J
860
500
10
680
1000
RT
200
C B R
48.6
Example

11

K

860
500
11
680
1000
RT
200
C B R
48.6
Comparative

Example

12

L

860
500
12
680
1000
RT
200
C B R
48.6
Comparative

Example

13

M

860

500
11
680
1000
RT
200
C B R
48.6
Comparative

Example

14

N

860
500
12
680
1000
RT
200
C B R
48.6
Comparative

Example

15

O

860
500
15
680
1000
RT
200
C B R
48.6
Comparative

Example

16

P

860
500
15
680
1000
RT
200
C B R
48.6
Comparative

Example

17
A
860
500
15
680
1000
RT
200
B D
48.6
Comparative

Example

18
B
860
500
15
680
1000
RT
200
B D
48.6
Comparative

Example

19
C
860
500
15
680
1000
RT
200
B D
48.6
Comparative

Example

20
Q
860
500
12
680
1000
RT
200
C B R
48.6
Example

21
R
830
500

6

680
1000
RT
150
C B R
48.6
Comparative

Example

22
S
850
500

7

670
550
RT
355
C B R
48.6
Comparative

Example

23
A
860
500
16
680
1100
RT
200
C B R
48.6
Example

24
A
860
500
16
680
1100
RT
200
C B R
48.6
Example

25
A
860
500
16
680
1100
RT
200
C B R
48.6
Example

Steel

Hot-rolling process
Cold-rolling process

tube
Steel
Transformation point (° C.)
Heating
Finishing
Coiling
Thickness
Reduction
Thickness

No.
No.
Ac₁
Ac₃
Ar₃
temperature
temperatur
temperature
(mm)
(%)
(mm)

26
A
740
899
859
1200
900
700
3
40
1.8

27
A
740
899
859
1200
900
700
3
40
1.8

28
A
740
899
859
1200
900
700
3
40
1.8

29
A
740
899
859
1200
900
700
3
40
1.8

30
A
740
899
859
1200
900
700
3
40
1.8

31
A
740
899
859
1200
900
700
3
40
1.8

32
A
740
899
859
1200
900
700
3
40
1.8

Annealing process
Tube

Heating and cooling conditions
Tempering
produc-
Tube

Aver-
Quenching
Aver-
Cooling
treatment
tion
size

Heating

age
start
age
stop
Heating
process
Outer

Steel

temper-
Hold-
cooling
temper-
cooling
temper-
temper-
Roll
diam-

tube
Steel
ature
ing
rate 1
ature
rate 2
ature
ature
forming
eter

No.
No.
(° C.)
time (s)
(° C./s)
(° C.)
(° C./s)
(° C.)
(° C.)
method
(mmφ)
Reference

26
A

910

500
15
680
1000
RT
200
—*
—
Comparative

Example

27
A

700

500
15
680
800
RT
200
—*
—
Comparative

Example

28
A
860
500
15

580

600
RT
200
—*
—
Comparative

Example

29
A
860
500
15

800

1000
RT
200
—*
—
Comparative

Example

30
A
860
500
15
680

50

RT
200
—*
—
Comparative

Example

31
A
860
500
15
680
1000
RT

100

—*
—
Comparative

Example

32
A
860
500
15
680
1000
RT

350

—*
—
Comparative

Example

*) —* : Tube was not produced

Cooling rate 1: Cooling rate in the temperature range from the heat holding temperature to the temperature at the start of quenching

Cooling rate 2: Cooling rate from the temperature at the start of quenching to 200° C.

TABLE 3

Material for steel tube (cold-rolled annealed sheet)
Properties of electric

Structure

Structure

Martensite
Tensile characteristics

Martensite

Steel

phase
0.2% proof
Tensile
Yield ratio

phase

tube
Steel

fraction
stress YS
strength TS
YR
Elongation El

fraction

No.
No.
Type*
(Vol %)
(MPa)
(MPa)
(%)
(%)
Type*
(Vol %)

1
A
F + M
52
870
1245
70
17
F + M
52

2
B
F + M
55
831
1190
70
18
F + M
55

3
C
F + M
58
880
1265
70
16
F + M
58

4
D
F + M
52
835
1201
70
17
F + M
52

5
E
F + M
51
877
1255
70
16
F + M
51

6
F
F + M
53
869
1245
70
16
F + M
53

7
G
F + M
52
839
1210
69
17
F + M
52

8
H
F + M
54
833
1189
70
16
F + M
54

9
I
F + M
55
840
1211
69
18
F + M
55

10
J
F + M
48
870
1245
70
18
F + M
48

11

K

F + P + M

10

591
845
70
22
F + P + M
10

12

L

F + M

65

933
1336
70
12
F + M
65

13

M

F + M
52
633
910
70
19
F + M
52

14

N

F + M
55
909
1311
69
11
F + M
55

15

O

F + M
45
770
1101
70
18
F + M
45

16

P

F + M

65

929
1340
69
12
F + M
65

17
A
F + M
52
883
1262
70
16
F + M
52

18
B
F + M
55
844
1210
70
16
F + M
55

19
C
F + M
58
901
1285
70
15
F + M
58

20
Q
F + M
52
875
1239
71
20
F + M
51

21
R
F + M
60
850
1227
69
16
F + M
60

22
S
F + M

70

860
1220
70
8
F + M
70

23
A
F + M
52
869
1243
70
18
F + M
52

24
A
F + M
53
858
1239
69
18
F + M
53

25
A
F + M
51
865
1226
71
19
F + M
51

26
A
F + M

80

955
1340
71
6
Tube was not

produced

27
A
F + P

0

630
756
83
18
Tube was not

produced

28
A
F + M
20
655
925
71
15
Tube was not

produced

29
A
F + M

80

945
1350
70
6
Tube was not

produced

30
A
F + P

0

628
765
82
18
Tube was not

produced

31
A
F + M
53
905
1245
73
8
Tube was not

produced

32
A
F + M
53
1001
1255
80
8
Tube was not

produced

*)F: ferrite, M: martensite, B: bainite, P: pearlite

TABLE 4

Properties of electric resistance welded tubes

Tensile characteristics
Properties after application of 2% prestrain → finishing

0.2%

Yield

Steel

proof
Tensile
Yield ratio
Elongation
0.2% proof
Tensile
ratio YR

tube
Steel
stress YS
strength TS
YR
El
stress YS
strength TS
YR
BH value

No.
No.
(MPa)
(MPa)
(%)
(%)
(MPa)
(MPa)
(%)
Minimum
Maximum
Reference

1
A
1002
1265
79
14
1325
1355
98
110
125
Example

2
B
956
1210
79
15
1272
1301
98
112
122
Example

3
C
1027
1285
80
13
1345
1376
98
105
125
Example

4
D
951
1213
78
14
1280
1300
98
110
123
Example

5
E
1065
1276
83
12
1339
1365
98
112
115
Example

6
F
1023
1265
81
13
1321
1345
98
110
118
Example

7
G
1001
1233
81
14
1305
1333
98
112
120
Example

8
H
996
1206
83
13
1271
1296
98
115
122
Example

9
I
987
1236
80
14
1295
1321
98
115
125
Example

10
J
978
1265
77
15
1320
1346
98
112
118
Example

11

K

756

856

88
18
921
945
97

30

35
Comparative

Example

12

L

1239
1356

91

8

1410
1443
98
110
125
Comparative

Example

13

M

780

925

84
16
988
1016
97
115
125
Comparative

Example

14

N

1121
1321
85

8

1375
1421
97
100
125
Comparative

Example

15

O

905

1121

81
15
1201
1233
97
105
119
Comparative

Example

16

P

1159
1353
86

8

1410
1441
98
102
125
Comparative

Example

17
A
1246
1288

97

8

1350
1371
98

90

125
Comparative

Example

18
B
1187
1235

96

8

1289
1315
98

90

135
Comparative

Example

19
C
1256
1305

96

7

1356
1389
98

90

135
Comparative

Example

20
Q
999
1258
79
17
1326
1352
98
112
125
Example

21
R
985
1233
80
12
1246
1356
92

56

65
Comparative

Example

22
S
978
1239
79

5

1238
1345
92

45

56
Comparative

Example

23
A
1003
1266
79
15
1328
1352
98
110
124
Example

24
A
989
1256
79
16
1321
1348
98
112
124
Example

25
A
979
1248
78
17
1329
1339
99
113
123
Example

Properties of electric resistance welded tubes

Tensile characteristics
Properties after finishing baking

Steel

0.2% proof
Tensile
Yield
Elongation
0.2%
Tensile
Yield ratio YR

tube
Steel
stress YS
strength TS
ratio YR
El
proof
strength TS
YR
BH value

No.
No.
(MPa)
(MPa)
(%)
(%)
(MPa)
(MPa)
(%)
Minimum
Maximum
Reference

26
A
Tube was not produced
Comparative

Example

27
A
Tube was not produced
Comparative

Example

28
A
Tube was not produced
Comparative

Example

29
A
Tube was not produced
Comparative

Example

30
A
Tube was not produced
Comparative

Example

31
A
Tube was not produced
Comparative

Example

32
A
Tube was not produced
Comparative

Example

TABLE 5

Properties before baking
Conditions of baking

finishing
finishing *

0.2%

Heating
Hold-
Properties after baking finishing

Test
Steel
proof
Tensile
Yield
tempera-
ing
0.2% proof
Tensile
Yield

speci-
tube
stress YS
strength
ratio
ture
time
stress YS
strength
ratio
BH value (MPa)

men No.
No.
(MPa)
(MPa)
YR
(° C.)
(min)
(MPa)
(MPa)
YR
Minimum
Maximum

A1
1
870
1245
70

100

10
1184
1352
88

2

7

A2
1
870
1245
70

100

15
1184
1354
87

2

8

A3
1
870
1245
70

100

20
1185
1350
88

3

6

A4
1
870
1245
70

100

25
1186
1355
88

4

8

A5
1
870
1245
70

100

30
1187
1352
88

5

10

A6
1
870
1245
70

150

10
1215
1350
90

33

105

A7
1
870
1245
70

150

15
1232
1355
91

50

60

A8
1
870
1245
70

150

20
1249
1360
92

67

79

A9
1
870
1245
70

150

25
1265
1358
93

83

95

A10
1
870
1245
70

150

30
1279
1355
94

97

115

A11
1
870
1245
70
170

5

1275
1355
94

93

115

A12
1
870
1245
70
170
10
1282
1354
95
100
110

A13
1
870
1245
70
170
15
1322
1352
98
140
121

A14
1
870
1245
70
170
20
1325
1355
98
110
125

A15
1
870
1245
70
170
25
1329
1360
98
147
126

A16
1
870
1245
70
170
30
1332
1365
98
150
132

A17
1
870
1245
70
200

5

1281
1365
94

99

132

A18
1
870
1245
70
200
10
1336
1357
98
154
167

A19
1
870
1245
70
200
15
1335
1366
98
153
170

A20
1
870
1245
70
200
20
1334
1362
98
152
165

A21
1
870
1245
70
250

5

1281
1362
94

99

165

A22
1
870
1245
70
250
10
1338
1365
98
156
165

A23
1
870
1245
70
250
15
1340
1355
99
158
165

A24
1
870
1245
70
250
20
1338
1358
99
156
170

*) Underlined conditions are outside the preferable conditions for baking finishing

Number	Date	Country	Kind
2010-068499	Mar 2010	JP	national
2011-015076	Jan 2011	JP	national

HIGH-STRENGTH ELECTRIC RESISTANCE WELDED STEEL TUBE AND PRODUCTION METHOD THEREFOR

Information

Publication Number

Date Filed

Date Published

Inventors

Original Assignees

CPC

US Classifications

International Classifications

Abstract

Description

Claims

Priority Claims (2)

CROSS REFERENCE TO RELATED APPLICATIONS

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