WO2013171884A1 - 金属材料の塑性加工方法及び塑性加工装置 - Google Patents
金属材料の塑性加工方法及び塑性加工装置 Download PDFInfo
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- WO2013171884A1 WO2013171884A1 PCT/JP2012/062691 JP2012062691W WO2013171884A1 WO 2013171884 A1 WO2013171884 A1 WO 2013171884A1 JP 2012062691 W JP2012062691 W JP 2012062691W WO 2013171884 A1 WO2013171884 A1 WO 2013171884A1
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D—WORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D22/00—Shaping without cutting, by stamping, spinning, or deep-drawing
- B21D22/20—Deep-drawing
- B21D22/208—Deep-drawing by heating the blank or deep-drawing associated with heat treatment
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21C—MANUFACTURE OF METAL SHEETS, WIRE, RODS, TUBES OR PROFILES, OTHERWISE THAN BY ROLLING; AUXILIARY OPERATIONS USED IN CONNECTION WITH METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL
- B21C37/00—Manufacture of metal sheets, bars, wire, tubes or like semi-manufactured products, not otherwise provided for; Manufacture of tubes of special shape
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21C—MANUFACTURE OF METAL SHEETS, WIRE, RODS, TUBES OR PROFILES, OTHERWISE THAN BY ROLLING; AUXILIARY OPERATIONS USED IN CONNECTION WITH METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL
- B21C51/00—Measuring, gauging, indicating, counting, or marking devices specially adapted for use in the production or manipulation of material in accordance with subclasses B21B - B21F
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D—WORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D22/00—Shaping without cutting, by stamping, spinning, or deep-drawing
- B21D22/02—Stamping using rigid devices or tools
- B21D22/022—Stamping using rigid devices or tools by heating the blank or stamping associated with heat treatment
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D—WORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D26/00—Shaping without cutting otherwise than using rigid devices or tools or yieldable or resilient pads, i.e. applying fluid pressure or magnetic forces
- B21D26/02—Shaping without cutting otherwise than using rigid devices or tools or yieldable or resilient pads, i.e. applying fluid pressure or magnetic forces by applying fluid pressure
- B21D26/021—Deforming sheet bodies
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D—WORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
- B21D37/00—Tools as parts of machines covered by this subclass
- B21D37/16—Heating or cooling
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- C—CHEMISTRY; METALLURGY
- C21—METALLURGY OF IRON
- C21D—MODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
- C21D1/00—General methods or devices for heat treatment, e.g. annealing, hardening, quenching or tempering
- C21D1/78—Combined heat-treatments not provided for above
-
- C—CHEMISTRY; METALLURGY
- C21—METALLURGY OF IRON
- C21D—MODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
- C21D11/00—Process control or regulation for heat treatments
-
- C—CHEMISTRY; METALLURGY
- C21—METALLURGY OF IRON
- C21D—MODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
- C21D7/00—Modifying the physical properties of iron or steel by deformation
- C21D7/02—Modifying the physical properties of iron or steel by deformation by cold working
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- C—CHEMISTRY; METALLURGY
- C21—METALLURGY OF IRON
- C21D—MODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
- C21D7/00—Modifying the physical properties of iron or steel by deformation
- C21D7/13—Modifying the physical properties of iron or steel by deformation by hot working
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- C—CHEMISTRY; METALLURGY
- C21—METALLURGY OF IRON
- C21D—MODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
- C21D8/00—Modifying the physical properties by deformation combined with, or followed by, heat treatment
- C21D8/005—Modifying the physical properties by deformation combined with, or followed by, heat treatment of ferrous alloys
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- C—CHEMISTRY; METALLURGY
- C21—METALLURGY OF IRON
- C21D—MODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
- C21D9/00—Heat treatment, e.g. annealing, hardening, quenching or tempering, adapted for particular articles; Furnaces therefor
- C21D9/46—Heat treatment, e.g. annealing, hardening, quenching or tempering, adapted for particular articles; Furnaces therefor for sheet metals
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N3/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N3/08—Investigating strength properties of solid materials by application of mechanical stress by applying steady tensile or compressive forces
- G01N3/18—Performing tests at high or low temperatures
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2203/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N2203/0014—Type of force applied
- G01N2203/0016—Tensile or compressive
- G01N2203/0017—Tensile
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2203/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N2203/0058—Kind of property studied
- G01N2203/0092—Visco-elasticity, solidification, curing, cross-linking degree, vulcanisation or strength properties of semi-solid materials
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2203/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N2203/02—Details not specific for a particular testing method
- G01N2203/022—Environment of the test
- G01N2203/0222—Temperature
- G01N2203/0226—High temperature; Heating means
Definitions
- the present invention relates to a plastic working method and a plastic working apparatus capable of forming a steel material containing austenite while suppressing the occurrence of necking and fracture.
- a steel material is preheated in a heating furnace or the like to Ac 3 or more points that become an austenite single phase region of about 750 ° C. to 1000 ° C. before press forming the steel material. .
- This austenite single-phase steel material is press-molded, and the steel material is quenched and quenched using heat transfer from the steel material to the mold to produce a press-molded product with high strength and good dimensional accuracy. To do.
- the die of the austenite is drawn while heating the die of the die and cooling the punch of the die.
- a part of the steel material that becomes the flange portion after forming is heated by heat transfer with the die to reduce its deformation resistance, and other parts of the steel material are also transferred by heat transfer with the punch.
- Drawing can be performed by cooling to increase its deformation resistance. Therefore, it is possible to perform drawing while preventing wrinkles and breakage.
- the metal structure of a work material that is a steel material is 70% of bainitic ferrite and / or granular bainitic ferrite as a matrix with a space factor. %,
- the retained austenite as the second structure is controlled to 5% to 30%, and the C concentration in the retained austenite is controlled to 1.0% by mass or more.
- Japanese Unexamined Patent Publication No. 2005-177805 Japanese Laid-Open Patent Publication No. 2007-1111765 Japanese Unexamined Patent Publication No. 2004-190050
- the present invention has been devised in view of the above-described problems, and uses a steel material containing austenite as a work material, and it is possible to improve the formability by suppressing the occurrence of constriction and breakage.
- An object is to provide a method and a plastic working apparatus.
- the gist of the present invention is as follows.
- One aspect of the present invention is a plastic working method of a steel material containing austenite, wherein the processing-induced transformation ductility maximum temperature of the steel material that changes depending on the strain ratio ⁇ is T ⁇ in units of ° C.
- the standard deviation of the limit equivalent strain approximation curve that depends on the strain ratio ⁇ that is lower than T ⁇ is ⁇ L ⁇
- the limit equivalent strain approximation curve that is dependent on the strain ratio ⁇ that is higher than T ⁇ is when the standard deviation .SIGMA.H beta, and wherein the T beta, and the?
- L .beta.x the strain from the T .beta.x the high temperature side the standard deviation of the limitations of equivalent strain trendline depends on the ratio .beta.x and .SIGMA.H .beta.x, when the T local the local temperature at the unit °C of the prediction broken portion, the T .beta.x from among the T beta, the? L beta the? L .beta.x from within, the .SIGMA.H .beta.x respectively selected from among the .SIGMA.H beta, and, a heating process of the local temperature T local may be heated so as to be within the first temperature range shown in equation 1 below; And a processing step of plastically deforming the steel material after the heating step.
- a plastic working apparatus for performing the plastic working method according to any one of (1) to (3) or (5) above includes: a housing part that houses the steel material and a mold; the steel material, A heating part that heats at least one of the mold and the surrounding space of the steel material; and a processing part that plastically deforms the steel material heated by the heating part by the mold.
- the plastic working apparatus according to (6) may further include a heat insulating member disposed so as to cover the housing portion.
- the plastic working apparatus according to (6) or (7) may further include a temperature measuring unit that measures the temperature of the steel material, the mold, and the space in the housing unit.
- the plastic working device according to (9) may further include a heat insulating member arranged to cover the housing portion.
- the plastic working device according to (9) or (10) may further include a temperature measuring unit that measures the temperature of the steel material, the mold, the space in the housing, and the heat medium. .
- the plastic working is performed in a temperature range including the processing-induced transformation ductility maximum temperature according to the strain ratio of the predicted fracture location of the steel material. It is possible to make the most of the transformation-induced plasticity phenomenon that occurs in steel materials. As a result, it is possible to provide a plastic working method and a plastic working apparatus that improve the formability by suppressing the occurrence of necking and fracture.
- FIG. 1 is a partially cutaway front view showing a schematic configuration of a plastic working apparatus according to an embodiment of the present invention. It is a partially notched front view which shows the schematic structure of the plastic working apparatus which concerns on another embodiment of this invention. It is a schematic diagram explaining a rectangular tube drawing process.
- a plastic working method according to an embodiment of the present invention will be described.
- a steel material containing austenite is used as a work material, and the transformation-induced plastic phenomenon that appears in this steel material is utilized to the maximum extent.
- FIG. 1 is a schematic diagram for explaining the TRIP phenomenon.
- a steel material (TRIP steel) containing austenite is subjected to tensile deformation, for example, constriction occurs after a certain degree of deformation.
- the necking occurs, the stress acting on the necking portion increases, and this stress causes a work-induced transformation (shown as A in FIG. 1) in which the retained austenite is transformed into martensite. Since martensite has a higher strength than other microstructures, the constricted portion is strengthened more than other portions by processing-induced transformation, and deformation of the constricted portion does not proceed.
- the deformation proceeds at a relatively low strength portion near the constricted portion.
- TRIP phenomenon transformation-induced plasticity phenomenon
- the above-mentioned TRIP phenomenon has temperature dependence.
- the improvement in ductility due to this TRIP phenomenon appears only in a specific temperature range.
- the temperature at which the ductility is most improved by the TRIP phenomenon (hereinafter referred to as the processing-induced transformation ductile maximum temperature) depends on the chemical composition and metal structure of the TRIP steel.
- this processing-induced transformation ductile maximum temperature is affected by the strain ratio ⁇ (plastic deformation mode) during plastic deformation, and the value changes depending on the strain ratio ⁇ . It became clear that it also has (plastic deformation mode dependence).
- FIG. 2 is a schematic diagram for explaining uniaxial tension, plane strain tension, and equibiaxial tension. As shown in FIG.
- a is uniaxial tension
- Corresponding to a is plane strain tensile
- the processing-induced transformation ductility maximum temperature which is a specific value for each steel material, and the plastic deformation that affects this processing-induced transformation ductility maximum temperature
- the strain ratio ⁇ plastic deformation mode
- T ⁇ the processing-induced transformation ductility maximum temperature
- FIG. 3 shows the temperature dependence of the critical equivalent strain ⁇ eq-critical at each strain ratio ⁇ investigated for the low carbon steel.
- the equivalent strain ⁇ eq is a strain calculated by the following equation A when the strain in the biaxial direction in the biaxial stress state is the maximum principal strain ⁇ 1 and the minimum principal strain ⁇ 2 , respectively. .
- the equivalent strain ⁇ eq is obtained by converting a stress-strain component in a multiaxial stress state into a corresponding uniaxial stress-strain.
- This equivalent strain ⁇ eq is used to compare different plastic deformation modes, that is, plastic deformability (ductility) at different strain ratios ⁇ .
- the critical equivalent strain ⁇ eq-critical is the equivalent strain ⁇ eq when a fracture occurs in the steel material as the workpiece.
- ⁇ eq ⁇ 4 ⁇ 3 ⁇ ( ⁇ 1 2 + ⁇ 2 2 + ⁇ 1 ⁇ 2 ) ⁇ 1/2 (formula A)
- the limit equivalent strain ⁇ eq-critical increases in a specific temperature range.
- this improvement in ductility is due to the occurrence of the TRIP phenomenon.
- deformation-induced transformation ductile maximum temperature T beta is shown to vary.
- the processing-induced transformation ductility maximum temperature T ⁇ 0.5 150 ° C.
- the processing-induced transformation ductility maximum temperature T 0 200.
- the processing-induced transformation ductility maximum temperature T 1.0 250 ° C.
- the processing-induced transformation ductile maximum temperature T ⁇ has a strain ratio ⁇ dependency.
- the temperature at which the critical equivalent strain ⁇ eq-critical is most improved by the TRIP phenomenon is the processing-induced transformation ductility maximum temperature T 0 of 200 ° C.
- the temperature at which the limit equivalent strain ⁇ eq-critical is improved has a specific range.
- the temperature range in which the limit equivalent strain ⁇ eq-critical is improved can be obtained from an approximated curve assuming that it follows a normal distribution curve indicated by a dotted line in FIG.
- the strain ratio is ⁇
- the critical equivalent strain ⁇ eq ⁇ is higher than the processing-induced transformation ductile maximum temperature T ⁇ , which is the temperature at which the critical equivalent strain ⁇ eq-critical is most improved.
- T ⁇ the processing-induced transformation ductile maximum temperature
- ⁇ eq-critical critical equivalent strain
- T temperature
- T ⁇ processing-induced transformation ductile maximum temperature
- ⁇ L ⁇ strain ratio ⁇ lower than T ⁇ Standard deviation of the dependent strain equivalent curve depending on the strain
- ⁇ H ⁇ Standard deviation of the critical strain approximate curve depending on the strain ratio ⁇ higher than T ⁇
- e Natural logarithm
- ⁇ Circumference ratio
- C 1 ⁇ C 4 means a constant.
- the temperature range to improve the limit equivalent strain epsilon eq-critical is the TRIP phenomenon is capable represented by the above? L beta and .SIGMA.H beta. That is, this temperature range is, for example, (T ⁇ ⁇ 3 ⁇ ⁇ L ⁇ ) to (T ⁇ + 3 ⁇ ⁇ H ⁇ ), (T ⁇ ⁇ 2 ⁇ ⁇ L ⁇ ) to (T ⁇ + 2 ⁇ ⁇ H ⁇ ), or ( T ⁇ - ⁇ L ⁇ ) to (T ⁇ + ⁇ H ⁇ ).
- the integrated value of the probability density function is 0.9974
- the range is (T ⁇ ⁇ 2 ⁇ ⁇ L ⁇ ) to (T ⁇ + 2 ⁇ ⁇ H ⁇ )
- the integrated value of the probability density function is 0.9544
- the above range is (T ⁇ ⁇ L ⁇ ) to (T In the case of [beta] + [sigma] H [ beta] ), it means mathematically that the integrated value of the probability density function is 0.6826.
- L beta and .SIGMA.H beta is the standard deviation of the curve approximated assumed to follow a normal distribution curve (limit equivalent strain approximate curve) Can be used to express.
- ⁇ L ⁇ and ⁇ H ⁇ are values depending on the strain ratio ⁇ .
- L 0 is 55 ° C.
- .SIGMA.H 0 is 19 ° C.
- the analysis of the approximate curve for obtaining ⁇ L ⁇ and ⁇ H ⁇ can be performed by a general data analysis / graph creation application or a spreadsheet application having a general graph creation function.
- the temperature range in which the limit equivalent strain ⁇ eq-critical is improved by the TRIP phenomenon is 35 ° C. to 257 ° C. in the case of (T 0 ⁇ 3 ⁇ ⁇ L 0 ) to (T 0 + 3 ⁇ ⁇ H 0 ),
- the case of (T 0 -2 ⁇ ⁇ L 0 ) to (T 0 + 2 ⁇ ⁇ H 0 ) is 90 ° C. to 238 ° C.
- the case of (T 0 ⁇ L 0 ) to (T 0 + ⁇ H 0 ) is 145 ° C. to 219 ° C. It can be expressed as ° C.
- the lower limit of this temperature range is (T ⁇ ⁇ 1.75 ⁇ ⁇ L ⁇ ), (T ⁇ ⁇ 1.5 ⁇ ⁇ L ⁇ ), or (T ⁇ ⁇ 1.25 ⁇ ⁇ L ⁇ ). Also good.
- the upper limit of this temperature range may be (T ⁇ + 1.20 ⁇ ⁇ H ⁇ ), (T ⁇ + 1.15 ⁇ ⁇ H ⁇ ), or (T ⁇ ⁇ 1.10 ⁇ ⁇ L ⁇ ).
- the limit equivalent strain ⁇ eq-critical is improved by the TRIP phenomenon.
- the temperature range is 90 ° C. to 223.75 ° C.
- the plastic working may be performed in the temperature range of 90 ° C. to 223.75 ° C. .
- the following plastic working method is used to form a steel material that uses austenite-containing steel material (TRIP steel) as a work material and minimizes necking and fracture.
- TRIP steel austenite-containing steel material
- L beta measured in advance and the standard deviation .SIGMA.H beta limit equivalent strain trendline depends the T beta strain ratio beta is a high temperature side as a reference, (2) the most constricted or breakage at the time of molding
- ⁇ L ⁇ x is low
- the T .beta.x basis represents the standard deviation limits of equivalent strain trendline depends on strain ratio .beta.x a temperature side
- .SIGMA.H .beta.x the standard limit equivalent strain trendline depends a T .beta.x strain ratio .beta.x the high temperature side as a reference Expresses the deviation. Incidentally, T .beta.x,?
- L .beta.x, and .SIGMA.H .beta.x is measured in advance for each strain ratio beta, T beta, is a value contained in? L beta, and .SIGMA.H beta.
- T ⁇ x, ⁇ L ⁇ x, and the ⁇ H ⁇ x, T ⁇ , ⁇ L ⁇ , and measurement and analysis methods and .SIGMA.H beta are the same.
- the plastic working method of the present embodiment uses a steel material containing austenite as a work material: the work-induced transformation ductility maximum temperature of the steel material, which changes depending on the strain ratio ⁇ , in T and beta, the standard deviation limits of equivalent strain trendline depends on the strain ratio beta is a lower temperature side than the T beta and? L beta, limit corresponding to depend on the strain ratio beta is a high temperature side than the T beta when the standard deviation of the strain approximate curve was .SIGMA.H beta, and the T beta, and the?
- the steel material used as a workpiece measures the strain induced transformation ductile maximum temperature T beta in each strain ratio beta in units ° C..
- Method of measuring the strain induced transformation ductile maximum temperature T beta include, but are not limited to, by changing the length and width of the test piece, a spherical head overhanging test for fixing the test piece end, be carried out at each temperature Good.
- the temperature at which the limit equivalent strain ⁇ eq-critical (ductility) is most improved is defined as a processing-induced transformation ductility maximum temperature T ⁇ at the strain ratio ⁇ .
- the standard deviation of the limit equivalent strain approximation curve that depends on the strain ratio ⁇ on the lower temperature side than T ⁇ and the limit equivalent on the strain ratio ⁇ on the higher temperature side than T ⁇
- the standard deviation of the strain approximate curve is obtained by the above approximate curve analysis.
- the local region (predicted fracture location) where the steel material is most likely to be constricted or broken is specified, and the strain ratio ⁇ x is specified as the plastic deformation mode of this local region. To do. Then, the strain ratio ⁇ x is selected from the strain ratio ⁇ measured in the physical property analysis step.
- the method for measuring the predicted fracture location and the strain ratio ⁇ x at that location is not particularly limited, but a scribed circle test may be performed.
- plastic deformation simulation using the finite element method is performed. It may be used. At this time, many commercially available plastic deformation simulation programs for computers may be used. If the plastic deformation simulation is used, it is possible to identify the predicted fracture location and analyze the strain ratio ⁇ x at that location, even when the inside of the workpiece becomes the predicted fracture location, which is difficult to measure. Since the validity of the simulation result only needs to be confirmed by an experiment, the predicted fracture location and the strain ratio ⁇ x at that location can be analyzed with the minimum number of experiments.
- the local temperature T local prediction broken portion of the steel material the temperature range corresponding to strain ratio .beta.x the point (T ⁇ x -2 ⁇ ⁇ L ⁇ x) ⁇ (T ⁇ x + 1.25 ⁇ ⁇ H ⁇ x ) To control the temperature.
- the first temperature range for example, (T ⁇ x - ⁇ L ⁇ x) ⁇ (T ⁇ x + ⁇ H ⁇ x) or (T ⁇ x -0.5 ⁇ ⁇ L ⁇ x ) ⁇ (T ⁇ x + 0.5 ⁇ ⁇ H ⁇ x) may be set forth.
- the temperature displacement ⁇ T local of the local temperature T local at the predicted fracture location that changes due to heat exchange or heat generation during plastic processing is expressed in ° C.
- the local temperature T local is changed to the second temperature shown in the following formula E in consideration of the temperature displacement ⁇ T local instead of the first temperature range shown in the formula D.
- the temperature may be controlled so as to be within the range.
- the following effects can be obtained by considering the temperature displacement ⁇ T local of the local temperature T local of the steel material that changes due to heat exchange or heat generated during plastic working. For example, plastic deformation with a slow strain rate, and even when the temperature change of the steel material is large compared with the beginning of the plastic processing and the end of the plastic processing where the steel material is constricted or fractured, the plastic deformation ability is the highest.
- the local temperature T local at the predicted fracture location can be controlled within the temperature range where the effect of improving ductility can be obtained.
- the local temperature T local can be controlled within a temperature range in which the effect of improving ductility can be obtained. If it is desired to obtain a most preferred ductility improvement effect is optionally the second temperature range, (T ⁇ x - ⁇ T local - ⁇ L ⁇ x ) ⁇ (T ⁇ x - ⁇ T local + ⁇ H ⁇ x) or (T .beta.x -.DELTA.T local -0.5 ⁇ ⁇ L ⁇ x) ⁇ ( T ⁇ x - ⁇ T local + 0.5 ⁇ ⁇ H ⁇ x) may be set forth.
- the analysis of the temperature displacement ⁇ T local in the deformation mode analysis step described above may be performed by actually measuring the local temperature T local at the predicted fracture location during plastic deformation by attaching a thermocouple or the like to the predicted fracture location.
- the temperature displacement ⁇ T local may be analyzed in addition to the analysis of the predicted fracture location and the strain ratio ⁇ x of the location using the plastic deformation simulation using the finite element method described above.
- the steel material, the mold, or the steel material is made so that the local temperature T local at the predicted fracture location is within the first temperature range or the second temperature range in which the effect of improving ductility is obtained. It is preferable to heat at least one of the surrounding spaces. For example, when it is found that there are a plurality of predicted fracture locations in the deformation mode analysis step, and the strain ratio ⁇ is different between the plurality of predicted fracture locations, in the heating step, the steel material, the mold Alternatively, by heating at least one of the surrounding space of the steel material, the temperature of each of the plurality of predicted fracture locations is within the first temperature range or the second temperature range suitable for the strain ratio ⁇ . It is preferable to control the temperature. As a result, the effect of improving ductility can be obtained at each of a plurality of predicted fracture locations. Moreover, in the said heating process, you may cool at least one of the surroundings of steel materials, a metal mold
- the steel material whose temperature is controlled so that the local temperature T local at the predicted fracture location in the heating step is within the first temperature range or the second temperature range in which the ductility improvement effect is obtained
- the plastic working method is not particularly limited. As a plastic working method, free forging, die forging, press working using a die, or the like may be performed.
- oils such as silicon oil, air, inert gas, water vapor mist, etc.
- a heat medium such as oil mist or the like may be heated, and the steel material as a workpiece may be plastically deformed by the pressure of the heat medium in the above-described processing step.
- the plastic deformation part of the workpiece is heated uniformly, and the plastic deformation proceeds in a more uniform state, so that it is possible to obtain an effect of improving the formability by delaying the arrival of fracture. is there.
- This embodiment is a plastic working method in which a steel material containing austenite is used as a work material: the work-induced transformation ductility maximum temperature of the steel material that changes depending on the strain ratio ⁇
- the standard deviation of the limit equivalent strain approximation curve that depends on the strain ratio ⁇ on the lower temperature side than T ⁇ is ⁇ L ⁇
- the limit equivalent strain that depends on the strain ratio ⁇ on the higher temperature side than T ⁇ when the standard deviation of the approximated curve was .SIGMA.H beta, and the T beta, and the?
- L .beta.x at high temperature side of the T .beta.x the standard deviation of the limitations of equivalent strain trendline depends on some the strain ratio .beta.x and .SIGMA.H .beta.x, when the T local the local temperature of the prediction broken portion in the unit ° C., the T .beta.x from among the T beta, the the? L .beta.x from the? L beta, the .SIGMA.H .beta.x from among the .SIGMA.H beta selected respectively, and the local temperature T local may be heated so as to be within the first temperature range shown in formula D of the heating And a processing step for plastically deforming the steel material after the heating step.
- the temperature displacement of the local temperature T local that changes during plastic deformation in the processing step is ⁇ T local in units of ° C.
- the temperature displacement ⁇ T local is further analyzed in the deformation mode analysis step.
- heating may be performed so that the local temperature T local is within the second temperature range represented by the above formula E.
- the steel material, the mold, or the surrounding space of the steel material so that the local temperature T local is in the first temperature range or the second temperature range. At least one may be heated.
- the heating medium is heated so that the local temperature T local is in the first temperature range or the second temperature range; in the processing step, the pressure of the heating medium is Thus, the steel material may be plastically deformed.
- the predicted fracture location and the strain ratio ⁇ x may be analyzed using a plastic working simulation.
- the temperature displacement ⁇ T local may be analyzed using a plastic working simulation.
- FIG. 5 is a partially cutaway front view showing a schematic configuration of the plastic working apparatus according to the first embodiment of the present invention.
- the main body frame 11 is for attaching each component constituting the plastic working apparatus 1 such as a set of molds 21 and the like, and a bolster 12 is disposed at an inner lower portion thereof, and a slide 13 is disposed at an inner upper portion thereof. It is arranged.
- the slide 13 is configured to be driven in the vertical direction by a slide driving device 14 such as a motor or a cylinder disposed on the upper portion of the main body frame 11.
- the upper mold 21 is attached to the lower surface of the slide 13, and the lower mold 21 is attached to the upper surface of the bolster 12.
- the plastic working apparatus 1 is attached to the main body frame 11 in a state where the pair of molds 21 are arranged to face each other, and the slide 13 moves up and down to move between the pair of molds 21.
- the workpiece 3 is configured to be able to perform plastic working. As long as the plastic working of the workpiece 3 can be performed by the pair of molds 21 as described above, the configuration of the main body frame 11 and the like of the plastic working device 1 is not particularly limited.
- the set of molds 21 performs plastic working such as bending, drawing, flange forming, burring, and overhanging on the workpiece 3 disposed between them.
- the shape is adjusted according to the type and the shape of the molded product, and a known configuration is used.
- the set of molds 21 includes a workpiece 3 placed on the lower mold 21 in a recess 21 a provided on the lower mold 21 by a convex part 21 b provided on the upper mold 21.
- the workpiece 3 is configured to bend by driving the upper mold 21 so as to enter.
- the set of molds 21 may be provided with, for example, a blank holder for performing drawing.
- the set of molds 21 may be configured such that the upper mold 21 and the lower mold 21 are provided with recesses 21a and the workpiece 3 is die forged.
- the plastic working apparatus 1 of the present embodiment includes a heater 31 that heats the atmosphere in the space 16 including the workpiece 3 and the pair of molds 21 as a heating unit, and a heater that heats the pair of molds 21. 32.
- the heating unit includes a heating furnace 33 that is disposed outside the plastic working apparatus 1 and heats the workpiece 3.
- the plastic working apparatus 1 may be configured to include at least one of the heater 31, the heater 32, and the heating furnace 33. In the configuration having the heater 31, the heater 31 heats the atmosphere in the space 16, so that the temperature difference between the workpiece 3 and the space 16 is intentionally small or large. Can be heated.
- the heater 32 heats the set of molds 21, so that the temperature difference between the workpiece 3 and the mold 21 is intentionally made relatively small, or this temperature difference. Can be heated.
- the temperature of the workpiece 3 before being installed in the space 16 of the plastic working apparatus 1 can be controlled to the target temperature.
- the heater 31, the heater 32, or the heating furnace 33 even when there are a plurality of predicted fracture locations in the workpiece 3, there are a plurality of predicted fracture locations. Each of these can be controlled to a temperature according to the location.
- the plastic working apparatus 1 has a cover 41 (a heat insulating cover, a heat insulating member) arranged so as to cover the space 16.
- the space 16 covered with the cover 41 functions as a housing portion that houses the workpiece 3.
- the heater 31 heats the atmosphere in the space 16 including the workpiece 3 and the pair of molds 21, and the heater 32 heats the mold 21, and the above-described predicted breakage points of the workpiece 3 are described above. What is necessary is just to be able to heat to one temperature range or the 2nd temperature range. Therefore, it does not specifically limit about those positions and structures, For example, you may be comprised from the induction heating coil, the burner, etc. other than the electric heater.
- the heater 31 is attached to the main body frame 11, and the heater 32 is attached to the inside of the mold 21.
- the heater 31, the heater 32, and the heating furnace 33 may have a cooling function for cooling to a temperature of room temperature or lower. In this case, even if the processing-induced transformation ductility maximum temperature T ⁇ of the workpiece 3 is not more than room temperature, the temperature of the predicted fracture location of the workpiece 3 can be controlled to the first temperature range or the second temperature range described above. preferable.
- the cover 41 surrounds the space 16 including the workpiece 3 and the pair of molds 21 to prevent heat radiation to the outside of the atmosphere in the space 16 and intrusion of outside air into the space 16. Is to be arranged.
- the cover 41 is composed of a heat insulating member that is a material having excellent heat insulation properties. For example, glass wool, aluminum film laminate, or the like is attached as a heat resistant material inside a metal outer frame having a water cooling function. Further, the cover 41 has an opening (not shown) and a door for taking in and out the workpiece.
- the cover 41 is formed in a box shape and is attached to the main body frame 11 so as to cover the side portion and the upper portion of the main body frame 11, but includes at least one set of molds 21.
- an insertion hole 41a for inserting the slide drive device 14 protruding from the upper part of the main body frame 11 and an insertion hole for inserting an inert gas introduction portion for introducing an inert gas described later are inserted.
- 41 b is formed on the cover 41.
- the plastic working device 1 of the present embodiment preferably further includes an inert gas introduction part 51.
- the inert gas introduction unit 51 includes, for example, a gas cylinder (not shown) and a metal pipe for replacing the atmosphere in the space 16 with an inert gas such as Ar or N 2 .
- the inert gas introduction part 51 By the inert gas introduction part 51, the surface oxidation of the workpiece 3 can be minimized.
- the shape, position and attachment method of the inert gas introduction part 51 are not particularly limited.
- the metal pipe attached to the insertion hole 41b formed in the cover 41 is configured to blow an inert gas such as Ar or N 2.
- the inert gas introduction part 51 may further include a vacuum deaeration pump (not shown).
- the plastic working apparatus 1 of the present embodiment further includes a temperature measuring unit.
- the temperature measuring unit is attached to each of the workpiece 3, the mold 21, and the space 16 so that the temperature of the workpiece 3, the mold 21, and the space 16 can be measured independently. It has a thermometer (not shown) and a display device. There are no particular limitations on the shape, position, and mounting method of the temperature measuring section. As the thermometer, a contact thermocouple thermometer or an infrared radiation thermometer may be used. In this embodiment, a thermocouple is used as the temperature measuring unit.
- the plastic working apparatus of the present embodiment described above will be summarized below.
- the plastic working apparatus according to the first embodiment of the present invention includes: a housing portion that houses a workpiece 3 (steel material) and a set of molds 21; a predicted fracture location of the workpiece 3 (steel material) Of the workpiece 3 (steel material), the set of molds 21, or the space 16 (the surrounding space of the steel material) so that the local temperature T local is within the first temperature range or the second temperature range.
- a heating unit that heats at least one; and a processing unit that plastically deforms the workpiece 3 (steel material) heated by the heating unit with a set of molds 21.
- the cover 41 heat insulation member arrange
- the temperature measuring part which measures the temperature of the to-be-processed material 3 (steel material), a pair of metal mold
- FIG. 6 is a partially cutaway front view showing a schematic configuration of a plastic working apparatus according to the second embodiment of the present invention.
- the plastic working apparatus 1 of the present embodiment performs plastic working on the workpiece 3 disposed between a pair of molds 21 and a heat medium.
- a heat medium whose pressure and temperature are controlled by the heat medium introduction unit 71 is introduced from the heat medium introduction hole 21 c provided in the lower mold 21 through the pipe 71 a.
- the workpiece 3 fixed between the upper mold 21 and the lower mold 21 by the slide driving device 14 is pushed into the recess 21 a provided in the upper mold 21 by the pressure of the heat medium.
- the target shape is given to the workpiece 3.
- oils such as silicon oil, gases such as air, inert gas, water vapor mist, and oil mist can be used.
- transducing part 71 is not specifically limited, What is necessary is just to be able to control the pressure and temperature of the said heat medium.
- the plastic working apparatus 1 of the present embodiment includes a heater 31 that heats the atmosphere in the space 16 including the workpiece 3 and the pair of molds 21 as a heating unit, and a heater that heats the pair of molds 21. 32 and a heater 34 for heating the heat medium.
- the heating unit includes a heating furnace 33 that is disposed outside the plastic working apparatus 1 and heats the workpiece 3.
- the predicted fracture location of the workpiece 3 can be controlled to a temperature corresponding to that location. Even if there are a plurality of predicted fracture locations in the workpiece 3, by controlling the four heating sources, each of the plurality of predicted fracture locations can be more preferably controlled to a temperature corresponding to the location. it can.
- the heater 31, the heater 32, the heater 34, and the heating furnace 33 may have a cooling function for cooling to a temperature below room temperature.
- the temperature of the predicted fracture location of the workpiece 3 can be controlled to the first temperature range or the second temperature range described above. preferable.
- the plastic working device 1 of the present embodiment has a cover 41 (a heat insulating cover, a heat insulating member) arranged so as to cover the space 16.
- the space 16 covered with the cover 41 functions as a housing portion that houses the workpiece 3.
- the plastic working apparatus 1 of the present embodiment further includes a temperature measuring unit.
- the temperature measuring unit can measure the temperature of each of the workpiece 3, the mold 21, the space 16, and the heat medium independently, so that the workpiece 3, the mold 21, the space 16, and It has a thermometer (not shown) and a display device attached to each of the heat medium introducing portions 71.
- a thermometer (not shown) and a display device attached to each of the heat medium introducing portions 71.
- the thermometer a contact thermocouple thermometer or an infrared radiation thermometer may be used.
- the plastic working apparatus of the present embodiment described above will be summarized below.
- the plastic working apparatus according to the second embodiment of the present invention includes: a housing portion that houses the workpiece 3 (steel material) and a set of molds 21; and heat that introduces a heat medium into the mold 21 Medium introduction part; Work material 3 (steel material), a set of gold so that the local temperature T local of the predicted fracture location of work material 3 (steel material) is within the first temperature range or the second temperature range At least one of the mold 21, the space 16 (the surrounding space of the steel material), or the heating medium is a heating unit; the workpiece 3 (steel material) heated by the heating unit is plastically deformed by the pressure of the heating medium. And a processing section to be provided.
- a cover 41 heat insulating member arranged to cover the housing portion is further provided.
- the workpiece 3 steel material
- the set of molds 21, the space 16 (the space in the accommodating portion), and the temperature measuring unit that measures the temperature of the heat medium are further provided.
- the conditions in the examples are one example of conditions used for confirming the feasibility and effects of the present invention, and the present invention is based on this one example of conditions. It is not limited.
- the present invention can adopt various conditions as long as the object of the present invention is achieved without departing from the gist of the present invention.
- each strain ratio ⁇ and limit equivalent strain ⁇ eq-critical at each temperature were measured using a steel material containing austenite (Example) and a steel material not containing austenite (Comparative Example). .
- the strain ratio ⁇ and the limit equivalent strain ⁇ eq-critical at each temperature were measured by changing the vertical and horizontal dimensions of the test piece and performing a ball head overhang test to fix the end of the test piece at each temperature. .
- the critical equivalent strain ⁇ eq-critical was calculated from the strain when necking or fracture occurred.
- Table 1 shows the measurement results of each strain ratio ⁇ and the limit equivalent strain ⁇ eq-critical at each temperature.
- the processing-induced transformation ductility maximum temperature T1.0 is 150 ° C.
- the limit equivalent strain ⁇ eq-critical changes depending on the steel material type, the processing temperature, and the strain ratio ⁇ .
- Comparative Example 6 as shown in Table 1, the temperature at which the limit equivalent strain ⁇ eq-critical is most improved does not depend on the strain ratio ⁇ . That is, there is no strain ratio ⁇ dependence on the processing-induced transformation ductility maximum temperature T ⁇ . This is because the TRIP phenomenon does not occur because the steel material does not contain austenite (comparative example).
- the limit is caused by the TRIP phenomenon on the basis of the processing-induced transformation ductility maximum temperature T ⁇ . It can be determined that the temperature range in which the equivalent strain ⁇ eq-critical is improved is 90 ° C. to 224 ° C.
- FIG. 7 is a schematic diagram for explaining the rectangular tube drawing process.
- a rectangular tube drawing process is performed on a blank 64 (workpiece) using an 80 mm square die 61, a 75 mm square tube punch 62, and a holder 63.
- Example 3 shown in Table 1 is used as a workpiece, and the steel material, the mold, or the local temperature T local of the predicted fracture location is 25 ° C. to 250 ° C., or At least one of the surrounding spaces was heated to control the temperature.
- a rectangular tube drawing process was performed on the steel material of Example 3 whose temperature was controlled in the heating step.
- Table 3 shows the results of a rectangular tube drawing process performed by using the steel material of Example 3 as a work material and heating it so that the local temperature T local at the predicted fracture location is 25 ° C to 250 ° C.
- the drawing height shown in Table 3 represents the height at which the workpiece can be molded without being constricted or broken, and the larger this value, the higher the moldability.
- the steel material of Example 3 has a processing-induced transformation ductility maximum temperature T ⁇ 0.5 of 150 ° C. Further, the steel material of Example 3, as shown in Table 2, in the case of beta -0.5, 2 ⁇ ? L -0.5 is 110 °C, 1.25 ⁇ ⁇ H -0.5 is 69 ° C. . That is, in the above-mentioned rectangular tube drawing, when the local temperature T local at the predicted fracture location is 40 ° C. to 219 ° C. (first temperature range), the drawing height is increased, and the T local is 150 It is expected that the draw height will be the highest when the temperature is 0C.
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Abstract
Description
(1)本発明の一態様は、オーステナイトを含有する鋼材の塑性加工方法であって:ひずみ比βに依存して変化する前記鋼材の加工誘起変態延性極大温度を単位℃でTβとし、前記Tβより低温度側である前記ひずみ比βに依存する限界相当ひずみ近似曲線の標準偏差をσLβとし、前記Tβより高温度側である前記ひずみ比βに依存する限界相当ひずみ近似曲線の標準偏差をσHβとしたとき、前記Tβと、前記σLβと、前記σHβとを、前記ひずみ比β毎に測定する物性解析工程と;前記鋼材を塑性変形させる際の予測破断箇所を特定し、前記予測破断箇所のひずみ比をβxとしたとき、前記ひずみ比βxを解析し、そして、前記ひずみ比βの中から前記ひずみ比βxを選択する変形様式解析工程と;前記ひずみ比βxに対する加工誘起変態延性極大温度を単位℃でTβxとし、前記Tβxより低温度側である前記ひずみ比βxに依存する限界相当ひずみ近似曲線の標準偏差をσLβxとし、前記Tβxより高温度側である前記ひずみ比βxに依存する限界相当ひずみ近似曲線の標準偏差をσHβxとし、前記予測破断箇所の局所温度を単位℃でTlocalとしたとき、前記Tβの中から前記Tβxを、前記σLβの中から前記σLβxを、前記σHβの中から前記σHβxをそれぞれ選択し、そして、前記局所温度Tlocalが下記の式1に示す第一温度範囲内となるように加熱する加熱工程と;前記加熱工程後の前記鋼材を塑性変形させる加工工程と;を備える。
Tβx-2×σLβx≦Tlocal≦Tβx+1.25×σHβx・・・(式1)
(2)上記(1)に記載の塑性加工方法では、前記加工工程での塑性変形中に変化する前記局所温度Tlocalの温度変位を単位℃でΔTlocalとしたとき、前記変形様式解析工程で、さらに、前記温度変位ΔTlocalを解析し;前記加熱工程で、前記局所温度Tlocalが下記の式2に示す第二温度範囲内となるように加熱してもよい。
Tβx-ΔTlocal-2×σLβx≦Tlocal≦Tβx-ΔTlocal+1.25×σHβx・・・(式2)
(3)上記(1)又は(2)に記載の塑性加工方法では、前記加熱工程で、前記局所温度Tlocalが前記温度範囲内となるように、前記鋼材、金型、または、前記鋼材の周囲空間のうちの少なくとも一つを加熱してもよい。
(4)上記(1)又は(2)に記載の塑性加工方法では、前記加熱工程で、前記局所温度Tlocalが前記温度範囲内となるように、熱媒体を加熱し;前記加工工程で、前記熱媒体の圧力により、前記鋼材を塑性変形させてもよい。
(5)上記(1)~(4)のいずれか一項に記載の塑性加工方法では、前記変形様式解析工程で、前記予測破断箇所と、前記ひずみ比βxと、前記温度変位ΔTlocalとを、塑性加工シミュレーションを用いて解析してもよい。
(6)上記(1)~(3)又は(5)のいずれか一項に記載の塑性加工方法を行う塑性加工装置は、前記鋼材と金型とを収容する収容部と;前記鋼材、前記金型、または、前記鋼材の周囲空間のうちの少なくとも一つを加熱する加熱部と;前記加熱部により加熱された前記鋼材を、前記金型により塑性変形させる加工部と;を備える。
(7)上記(6)に記載の塑性加工装置では、前記収容部を覆うように配置される断熱部材を更に備えてもよい。
(8)上記(6)又は(7)に記載の塑性加工装置では、前記鋼材、前記金型、及び前記収容部内の空間の温度を計測する測温部を更に備えてもよい。
(9)上記(1)、(2)、(4)又は(5)のいずれか一項に記載の塑性加工方法を行う塑性加工装置は、
前記鋼材と金型とを収容する収容部と;
前記金型内に前記熱媒体を導入する熱媒体導入部と;
前記鋼材、前記金型、前記鋼材の周囲空間、または、前記熱媒体のうちの少なくとも一つを加熱部と;
前記加熱部により加熱された前記鋼材を、前記熱媒体の圧力により塑性変形させる加工部と;を備える。
(10)上記(9)に記載の塑性加工装置では、前記収容部を覆うように配置される断熱部材を更に備えてもよい。
(11)上記(9)又は(10)に記載の塑性加工装置では、前記鋼材、前記金型、前記収容部内の空間、及び前記熱媒体の温度を計測する測温部を更に備えてもよい。
εeq={4÷3×(ε1 2+ε2 2+ε1ε2)}1/2 ・・・(式A)
・・・(式B)
・・・(式C)
Tβx-2×σLβx≦Tlocal≦Tβx+1.25×σHβx ・・・(式D)
Tβx-ΔTlocal-2×σLβx≦Tlocal≦Tβx-ΔTlocal+1.25×σHβx・・・(式E)
(1)本実施形態は、オーステナイトを含有する鋼材を被加工材とする塑性加工方法であって:ひずみ比βに依存して変化する上記鋼材の加工誘起変態延性極大温度を単位℃でTβとし、上記Tβより低温度側である上記ひずみ比βに依存する限界相当ひずみ近似曲線の標準偏差をσLβとし、上記Tβより高温度側である上記ひずみ比βに依存する限界相当ひずみ近似曲線の標準偏差をσHβとしたとき、上記Tβと、上記σLβと、上記σHβとを、上記ひずみ比β毎に測定する物性解析工程と;上記鋼材を塑性変形させる際の予測破断箇所を特定し、上記予測破断箇所のひずみ比をβxとしたとき、上記ひずみ比βxを解析し、そして、上記ひずみ比βの中から上記ひずみ比βxを選択する変形様式解析工程と;上記ひずみ比βxに対する加工誘起変態延性極大温度を単位℃でTβxとし、上記Tβxより低温度側である上記ひずみ比βxに依存する限界相当ひずみ近似曲線の標準偏差をσLβxとし、上記Tβxより高温度側である上記ひずみ比βxに依存する限界相当ひずみ近似曲線の標準偏差をσHβxとし、上記予測破断箇所の局所温度を単位℃でTlocalとしたとき、上記Tβの中から上記Tβxを、上記σLβの中から上記σLβxを、上記σHβの中から上記σHβxをそれぞれ選択し、そして、上記局所温度Tlocalが上記の式Dに示す第一温度範囲内となるように加熱する加熱工程と;上記加熱工程後の上記鋼材を塑性変形させる加工工程と;を備える。
(2)そして、上記加工工程での塑性変形中に変化する上記局所温度Tlocalの温度変位を単位℃でΔTlocalとしたとき、上記変形様式解析工程で、さらに、上記温度変位ΔTlocalを解析し;上記加熱工程で、上記局所温度Tlocalが上記の式Eに示す第二温度範囲内となるように加熱してもよい。
(4)そして、上記加熱工程で、上記局所温度Tlocalが上記第一温度範囲内または上記第二温度範囲内となるように、熱媒体を加熱し;上記加工工程で、上記熱媒体の圧力により、上記鋼材を塑性変形させてもよい。
(5)そして、上記変形様式解析工程で、上記予測破断箇所と、上記ひずみ比βxとを、塑性加工シミュレーションを用いて解析してもよい。加えて、上記温度変位ΔTlocalを、塑性加工シミュレーションを用いて解析してもよい。
本発明の第1実施形態に係る塑性加工装置について説明する。図5は、本発明の第1実施形態に係る塑性加工装置の概略的な構成を示す一部切欠正面図である。
(6)本発明の第1実施形態の塑性加工装置は、:被加工材3(鋼材)と一組の金型21とを収容する収容部と;被加工材3(鋼材)の予測破断箇所の局所温度Tlocalが第一温度範囲内または第二温度範囲内となるように、被加工材3(鋼材)、一組の金型21、または、空間16(鋼材の周囲空間)のうちの少なくとも一つを加熱する加熱部と;この加熱部により加熱された被加工材3(鋼材)を、一組の金型21により塑性変形させる加工部と;を備える。
(8)そして、被加工材3(鋼材)、一組の金型21、及び空間16(収容部内の空間)の温度を計測する測温部を更に備える。
次に、本発明の第2実施形態に係る塑性加工装置について説明する。図6は、本発明の第2実施形態に係る塑性加工装置の概略的な構成を示す一部切欠正面図である。
(9)本発明の第2実施形態の塑性加工装置は、:被加工材3(鋼材)と一組の金型21とを収容する収容部と;金型21内に熱媒体を導入する熱媒体導入部と;被加工材3(鋼材)の予測破断箇所の局所温度Tlocalが第一温度範囲内または第二温度範囲内となるように、被加工材3(鋼材)、一組の金型21、空間16(鋼材の周囲空間)、または、熱媒体のうちの少なくとも一つを加熱部と;この加熱部により加熱された被加工材3(鋼材)を、熱媒体の圧力により塑性変形させる加工部と;を備える。
(10)そして、上記収容部を覆うように配置されるカバー41(断熱部材)を更に備える。
(11)そして、被加工材3(鋼材)、一組の金型21、空間16(収容部内の空間)、及び熱媒体の温度を計測する測温部を更に備える。
3 被加工材(鋼材)
11 本体フレーム
12 ボルスタ
13 スライド
14 スライド駆動装置
16 空間(鋼材の周囲空間、収容部内の空間)
21 金型
31 空間16のヒータ(加熱部)
32 金型21のヒータ(加熱部)
33 被加工材3の加熱炉(加熱部)
41 保温カバー(断熱部材)
51 不活性ガス導入部
71 熱媒体導入部(加熱部)
Claims (11)
- オーステナイトを含有する鋼材の塑性加工方法であって:
ひずみ比βに依存して変化する前記鋼材の加工誘起変態延性極大温度を単位℃でTβとし、前記Tβより低温度側である前記ひずみ比βに依存する限界相当ひずみ近似曲線の標準偏差をσLβとし、前記Tβより高温度側である前記ひずみ比βに依存する限界相当ひずみ近似曲線の標準偏差をσHβとしたとき、前記Tβと、前記σLβと、前記σHβとを、前記ひずみ比β毎に測定する物性解析工程と;
前記鋼材を塑性変形させる際の予測破断箇所を特定し、前記予測破断箇所のひずみ比をβxとしたとき、前記ひずみ比βxを解析し、そして、前記ひずみ比βの中から前記ひずみ比βxを選択する変形様式解析工程と;
前記ひずみ比βxに対する加工誘起変態延性極大温度を単位℃でTβxとし、前記Tβxより低温度側である前記ひずみ比βxに依存する限界相当ひずみ近似曲線の標準偏差をσLβxとし、前記Tβxより高温度側である前記ひずみ比βxに依存する限界相当ひずみ近似曲線の標準偏差をσHβxとし、前記予測破断箇所の局所温度を単位℃でTlocalとしたとき、前記Tβの中から前記Tβxを、前記σLβの中から前記σLβxを、前記σHβの中から前記σHβxをそれぞれ選択し、そして、前記局所温度Tlocalが下記の式1に示す第一温度範囲内となるように加熱する加熱工程と;
前記加熱工程後の前記鋼材を塑性変形させる加工工程と;
を備えることを特徴とする塑性加工方法。
Tβx-2×σLβx≦Tlocal≦Tβx+1.25×σHβx・・・(式1) - 前記加工工程での塑性変形中に変化する前記局所温度Tlocalの温度変位を単位℃でΔTlocalとしたとき、前記変形様式解析工程で、さらに、前記温度変位ΔTlocalを解析し;
前記加熱工程で、前記局所温度Tlocalが下記の式2に示す第二温度範囲内となるように加熱する;
ことを特徴とする請求項1に記載の塑性加工方法。
Tβx-ΔTlocal-2×σLβx≦Tlocal≦Tβx-ΔTlocal+1.25×σHβx・・・(式2) - 前記加熱工程で、前記局所温度Tlocalが前記第一温度範囲内となるように、前記鋼材、金型、または、前記鋼材の周囲空間のうちの少なくとも一つを加熱することを特徴とする請求項1に記載の塑性加工方法。
- 前記加熱工程で、前記局所温度Tlocalが前記第一温度範囲内となるように、熱媒体を加熱し;
前記加工工程で、前記熱媒体の圧力により、前記鋼材を塑性変形させる;
ことを特徴とする請求項1に記載の塑性加工方法。 - 前記変形様式解析工程で、前記予測破断箇所と、前記ひずみ比βxと、前記温度変位ΔTlocalとを、塑性加工シミュレーションを用いて解析することを特徴とする請求項2に記載の塑性加工方法。
- 請求項1に記載の塑性加工方法を行う塑性加工装置であって:
前記鋼材と金型とを収容する収容部と;
前記鋼材、前記金型、または、前記鋼材の周囲空間のうちの少なくとも一つを加熱する加熱部と;
前記加熱部により加熱された前記鋼材を、前記金型により塑性変形させる加工部と;
を備えることを特徴とする塑性加工装置。 - 前記収容部を覆うように配置される断熱部材を更に備えることを特徴とする請求項6に記載の塑性加工装置。
- 前記鋼材、前記金型、及び前記収容部内の空間の温度を計測する測温部を更に備えることを特徴とする請求項6に記載の塑性加工装置。
- 請求項4に記載の塑性加工方法を行う塑性加工装置であって:
前記鋼材と金型とを収容する収容部と;
前記金型内に前記熱媒体を導入する熱媒体導入部と;
前記鋼材、前記金型、前記鋼材の周囲空間、または、前記熱媒体のうちの少なくとも一つを加熱する加熱部と;
前記加熱部により加熱された前記鋼材を、前記熱媒体の圧力により塑性変形させる加工部と;
を備えることを特徴とする塑性加工装置。 - 前記収容部を覆うように配置される断熱部材を更に備えることを特徴とする請求項9に記載の塑性加工装置。
- 前記鋼材、前記金型、前記収容部内の空間、及び前記熱媒体の温度を計測する測温部を更に備えることを特徴とする請求項9に記載の塑性加工装置。
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