CN114130812A - HRB600 high-strength anti-seismic steel bar rolling process - Google Patents

Abstract

The invention relates to a HRB600 high-strength anti-seismic steel bar rolling process, which relates to the technical field of steel bar rolling.A control module controls to convey a steel billet to a heating furnace through a conveying roller to be heated to a first preset temperature T1, and conveys the steel billet to a roughing mill for roughing when the heating is finished, so as to obtain roughing round steel; when rough rolling is finished, the acquisition module acquires the diameter D of the rough-rolled steel bar detected by the first laser diameter gauge, and when the rough-rolled steel bar is determined to be finished, the rough-rolled steel bar is cooled to a preset temperature range Ty through a water cooling tank; the control module controls the roll spacing of a driving roll and a driven roll of a finishing mill roll to be determined according to the diameter D, and the rough rolling round steel subjected to cooling is conveyed to a finishing mill for finish rolling to obtain finish rolling ribbed round steel; the control module conveys the finish rolled ribbed round steel subjected to finish rolling to a shearing machine for shearing and then naturally cools the sheared round steel to obtain the HRB600 high-strength anti-seismic reinforcing steel bar; the control precision of the rolling process is improved, and therefore the quality of the rolled steel bars is further improved.

Description

HRB600 high-strength anti-seismic steel bar rolling process

Technical Field

The invention relates to the technical field of steel bar rolling, in particular to a HRB600 high-strength anti-seismic steel bar rolling process.

Background

The hot-rolled ribbed steel bar is a novel building steel variety which develops rapidly at home and abroad in the late twentieth century. The hot-rolled ribbed steel bar has the advantages of high strength, good earthquake resistance and the like, and is a main product for building and bridge construction.

At present, the high-strength steel bars on the market are also HRB500 steel bars which are inferior to HRB600 steel bars in toughness and strength. The prior art hot rolled ribbed steel bar production facility generally uses a hot rolling unit to hot roll the steel bar stock to produce ribbed steel bars. At present, a common method adopts a controlled rolling and controlled cooling process to produce the steel bar simultaneously, namely low-temperature initial rolling, pre-water cooling before finish rolling and controlled cooling after finish rolling, but the method not only has the defects of large rolling pressure and high power consumption,

the HRB600 steel bar hot rolling has higher requirements on the metallographic structure, the yield strength and the tensile capacity, and the standard is stricter; therefore, the control precision of the rolling process of the existing hot rolling production technology based on the HBR500 cannot meet the production requirement of the HRB600 steel bar.

Disclosure of Invention

Therefore, the invention provides a HRB600 high-strength anti-seismic steel bar rolling process, which is used for solving the problem that the control precision of a hot rolling production technology in the prior art on a rolling process cannot meet the production requirement of an HRB600 steel bar.

In order to achieve the purpose, the invention provides a HRB600 high-strength anti-seismic steel bar rolling process, which comprises the following steps:

s1, the control module controls to convey the steel billet to the heating furnace through the conveying roller to be heated to a first preset temperature T1, and conveys the steel billet to the roughing mill to be roughly rolled when the heating is finished, so that roughly rolled round steel is obtained;

step S2, when rough rolling is completed, the obtaining module obtains the diameter D of the rough-rolled steel bar detected by the first laser diameter gauge, and when the rough-rolled steel bar is determined to be completed, the rough-rolled steel bar is cooled to a preset temperature range Ty through a water cooling tank;

step S3, the control module controls the roll spacing of a driving roll and a driven roll of a finishing mill roll to be determined according to the diameter D, and the roughly rolled round steel after being cooled is conveyed to a finishing mill to be finish rolled to obtain finish rolled ribbed round steel;

s4, conveying the finish-rolled ribbed round steel subjected to finish rolling to a shearing machine by a control module, shearing and naturally cooling to obtain the HRB600 high-strength anti-seismic steel bar;

in the step S3, the obtaining module obtains a pre-finish rolling temperature Tq of the rough rolled round steel detected by the first temperature sensor disposed above the conveying roller, obtains a finish rolling temperature Tz detected by the second temperature sensor disposed after the third finishing mill when the finish rolled round steel exits the third finishing mill, and obtains a diameter of the finish rolled round steel detected by the second laser diameter gauge, and the control module analyzes and determines whether the finish rolled round steel is qualified or not according to the diameter Dj of the finish rolled round steel, and adjusts parameters of the heating furnace, the rough rolling mill, and the finishing mill according to an analysis result when the finish rolled round steel is unqualified.

Further, in the step S3, when the control module determines the roller spacing between the driving roller and the driven roller of the front 3 finishing mill rollers according to the diameter D of the rough rolling round steel, the control module compares the diameter D of the rough rolling round steel with the preset diameter of the rough rolling round steel set therein, and determines the roller spacing of the finishing mill rollers according to the comparison result,

wherein the control module is provided with a first preset rough rolling round steel diameter D1, a second preset rough rolling round steel diameter D2, a third preset rough rolling round steel diameter D3, a first roller spacing H1, a second roller spacing H2 and a third roller spacing H3, wherein D1 is more than D2 and more than D3, H1 is more than H2 and more than H3,

when D is not more than D1, the control module determines that the roller spacing between the driving roller and the driven roller of the finishing mill roller is a first roller spacing H1;

when D1 is more than D and less than or equal to D2, the control module determines the roll spacing between the driving roll and the driven roll of the finishing mill roll to be a second roll spacing H2;

and when D2 is more than or equal to D3, the control module determines the roll spacing between the driving roll and the driven roll of the finishing mill roll to be the third roll spacing H3.

Further, in the step S3, when the rough rolled round steel is finish rolled, the control module analyzes and determines whether the finish rolled round steel is qualified according to the diameter Dj of the finish rolled round steel, the control module calculates the resilience W of the finish rolled round steel according to the diameter Dj of the finish rolled round steel and the roll inner diameter U of the 3 rd finishing mill, preliminarily determines whether the finish rolled round steel is qualified according to a comparison result between the resilience W and a preset resilience range W0, the preset resilience range W0 includes a minimum resilience Wmin and a maximum resilience Wmax,

if W belongs to W0, the control module preliminarily judges that the finish rolled round steel is qualified;

if W is larger than Wmax, the control module preliminarily judges that the finish rolling round steel is unqualified;

and if W is less than Wmin, the control module judges that the finish rolled round steel is unqualified.

Further, when the control module preliminarily judges that the finish rolled round steel is qualified, the control module obtains the elongation P of the finish rolled round steel finish rolled by the first three finish rolling mills, compares the elongation P with a preset elongation P0, determines whether the finish rolled round steel is qualified according to the comparison result,

if the P is larger than or equal to P0, the control module judges that the finish rolling round steel is qualified;

and if P is less than P0, the control module judges that the finish rolled round steel is unqualified.

Further, when the control module preliminarily judges that the finish rolled round steel is unqualified, the control module calculates a first springback difference value delta Wa between the springback value W and a preset maximum springback value Wmax, sets delta W to be W-Wmax, selects a corresponding distance adjusting coefficient according to a comparison result of the springback difference value and the preset springback difference value to adjust the roller distance,

wherein the control module is also provided with a first preset springback difference value delta W1, a second springback difference value delta W2, a third springback difference value delta W3, a first interval adjusting coefficient K1, a second interval adjusting coefficient K2 and a third interval adjusting coefficient K3, wherein delta W1 is more than delta W2 is more than delta W3, 0.5 is more than K3 is more than K2 is more than K1 is more than 1,

when the delta Wa is not more than delta W1, the control module selects a first spacing adjustment coefficient K1 to adjust the roller spacing;

when the delta W1 is larger than the delta Wa and is smaller than or equal to the delta W2, the control module selects a second spacing adjustment coefficient K2 to adjust the roller spacing;

when the delta W2 is larger than the delta Wa and is not larger than the delta W3, the control module selects a third distance adjusting coefficient K3 to adjust the roller distance;

when the control module selects the ith interval adjusting coefficient Ki to adjust the roller interval, setting i to be 1, 2 and 3, and setting the adjusted roller interval to be Hk by the control module, setting Hk to be Hn multiplied by Ki and n to be 1, 2 and 3.

Further, when the control module judges that the finish rolled round steel is unqualified and W is less than Wmin, the control module calculates a second springback difference value delta Wb between the springback value W and the preset minimum springback value Wmin, sets delta W to Wmin-W, selects a corresponding temperature regulating coefficient according to a comparison result of the second springback difference value and the preset springback difference value to regulate the first preset temperature T1,

wherein the control module is also provided with a first temperature regulating coefficient Kt1, a second temperature regulating coefficient Kt2 and a third temperature regulating coefficient Kt3, the setting is that Kt3 is more than 0.5 and more than Kt2 and more than Kt1 is less than 2,

when the delta Wb is less than or equal to the delta W1, the control module selects a first temperature adjusting coefficient Kt1 to adjust a first preset temperature T1;

when the delta W is more than or equal to delta W1 and the delta Wb is more than or equal to delta W2, the control module selects a second temperature adjusting coefficient Kt2 to adjust the first preset temperature T1;

when the delta W is more than or equal to delta W2 and the delta Wb is more than or equal to delta W3, the control module selects a third temperature adjusting coefficient Kt3 to adjust the first preset temperature T1;

when the control module selects the ith temperature adjustment coefficient Ktr to adjust the first preset temperature T1, r is set to 1, 2, and 3, the control module sets the adjusted first preset temperature to T1, and sets T2 to T1 × Ktr.

Further, when the control module judges that the round rolling bar is unqualified and P is less than P0, the control module calculates the finishing temperature difference delta Ta between the temperature Tq before finishing rolling and the finishing temperature Tz detected by the second temperature sensor, sets delta Ta to Tq-Tz, determines whether to adjust the frequency of the high-frequency generator after the third finishing mill according to the comparison result of the finishing temperature difference and the preset finishing temperature difference delta Ta0,

if Δ Ta > Δ Ta0, the control module determines to adjust the frequency of the high frequency generator;

if Δ Ta is less than or equal to Δ Ta0, the control module determines not to adjust the frequency of the high frequency generator.

Further, when the control module judges that the frequency of the high-frequency generator is adjusted, the control module calculates the elongation difference delta P between the elongation P and the preset elongation P0, sets the delta P to be P0-P, selects the corresponding frequency adjustment coefficient according to the comparison result of the elongation difference and the preset elongation difference for adjustment,

wherein the control module is further provided with a first preset elongation difference value delta P1, a second preset elongation difference value delta P2, a third preset elongation difference value delta P3, a first frequency adjusting coefficient Kp1, a second frequency adjusting coefficient Kp2 and a third frequency adjusting coefficient Kp3, wherein delta P1 is more than delta P2 is more than delta P3, 1 Kp1 is more than 1 Kp2 is more than 1 Kp3 is less than 1.5,

when the delta P is less than or equal to the delta P1, the control module selects a first frequency adjusting coefficient Kp1 to adjust the frequency of the high-frequency generator;

when the delta P is more than or equal to delta P1 and less than or equal to delta P2, the control module selects a second frequency adjusting coefficient Kp2 to adjust the frequency of the high-frequency generator;

when the delta P is more than or equal to delta P2 and less than or equal to delta P3, the control module selects a third frequency adjusting coefficient Kp3 to adjust the frequency of the high-frequency generator;

when the control module selects the e-th frequency adjustment coefficient Kpe to adjust the frequency of the high-frequency generator, the control module sets the adjusted frequency of the high-frequency generator to Pk, the Pk is set to Pm multiplied by Kpe, and Pm is the initial frequency of the high-frequency generator.

Further, when the control module finishes the frequency adjustment of the high-frequency generator, the control module selects a corresponding distance correction coefficient according to the comparison result of the elongation difference and a preset elongation difference to correct the roller distance,

wherein the control module is also provided with a first pitch correction coefficient X1, a second pitch correction coefficient X2 and a third pitch correction coefficient X3, wherein the setting is 0.7 < X3 < X2 < X1 < 1,

when the delta P is less than or equal to the delta P1, the control module selects a first pitch correction coefficient X1 to correct the roller pitch;

when the delta P is more than or equal to delta P1 and less than or equal to delta P2, the control module selects a second pitch correction coefficient X2 to correct the roll pitch;

when the delta P is more than or equal to delta P2 and less than or equal to delta P3, the control module selects a third pitch correction coefficient X3 to correct the roller pitch;

when the control module selects the s-th pitch correction coefficient Xs to correct the roller pitch, s is set to be 1, 2 and 3, and the control module sets the corrected roller pitch to be Hx which is set to be Hk multiplied by Xs.

Further, in the step S3, the control module determines an initial frequency of the high frequency generator based on a comparison of the pre-finish rolling temperature Tq and a preset pre-finish rolling temperature,

wherein the control module is also provided with a first preset temperature Tq1 before finish rolling, a second preset temperature Tq2 before finish rolling, a third preset temperature Tq3 before finish rolling, a first initial frequency P1, a second initial frequency P2 and a third initial frequency P3, wherein Tq1 is more than Tq2 and more than Tq3, P1 is more than P2 and more than P3,

when Tq is not greater than Tq1, the control module sets the initial frequency of the high-frequency generator to a first initial frequency P1;

when Tq1 < Tq ≦ Tq2, the control module sets the initial frequency of the high frequency generator to a second initial frequency P2;

when Tq2 < Tq ≦ Tq3, the control module sets the initial frequency of the high frequency generator to a third initial frequency P3.

Compared with the prior art, the invention has the beneficial effects that when the steel bar is finish rolled, the temperature sensors and the laser diameter measuring instruments are arranged among the plurality of finish rolling machines, whether the rough rolling and the finish rolling of the steel bar are qualified or not is determined according to the detection result of the laser diameter measuring instruments and the elongation rate of the steel bar during the finish rolling, and when the judgment is unqualified, the temperature of the heating furnace before the rough rolling is adjusted and/or the roller spacing during the finish rolling is adjusted, so that the control precision of the rolling process is improved, and the quality of the rolled steel bar is further improved.

Particularly, the laser diameter measuring instrument and the temperature sensor are arranged behind the third finishing mill to serve as detection points, so that the finishing mills before and after the detection points can be adjusted in the finish rolling process, unqualified steel bars are reduced, and the waste material amount is further reduced.

Particularly, the diameter of the steel bar rolled after the third finishing mill is detected by the laser diameter gauge, the resilience amount of the steel bar in the finishing process is calculated according to the detected diameter, whether the finished round steel is qualified or not is judged according to the resilience amount, and when the round steel is unqualified, the heating furnace, the roughing mill and the finishing mill are correspondingly subjected to parameter adjustment according to the actual resilience amount, so that the control precision of the rolling process is further improved, and the quality of the rolled steel bar is further improved.

Furthermore, the control module is provided with a plurality of preset rough rolling round steel diameters and roll intervals, the diameters of the rough rolling round steel are detected after rough rolling and cooling of the water cooling tank, and the roll intervals of the rolls of the finish rolling mill during finish rolling are determined according to the actual detection result and the comparison result of the preset rough rolling round steel diameters, so that the control precision of the rolling process is further improved, and the quality of the rolled steel bars is further improved.

Furthermore, the control module is provided with a preset resilience range and a preset elongation, the resilience of the finish rolling round steel is calculated according to the diameter of the finish rolling round steel detected by the laser diameter gauge and the inner diameter of the roller of the third finish rolling mill, and whether the finish rolling round steel is qualified or not is judged according to the comparison result of the resilience and the preset resilience range and the comparison result of the actual elongation and the preset elongation, so that the control precision of the rolling process is further improved, and the quality of the rolled steel bar is further improved.

Furthermore, the control module is provided with a plurality of preset springback difference values and spacing adjustment coefficients, when the finish rolling round steel is preliminarily judged to be unqualified and the springback is too large, the springback difference value between the actual springback and the preset maximum springback is calculated, and the corresponding spacing adjustment coefficient is selected according to the comparison result of the springback difference value and the preset springback difference value to adjust the spacing of the rolls of the finish rolling mill, so that the control precision of the rolling process is further improved, and the quality of the rolled steel bar is further improved.

Furthermore, the control module is provided with a plurality of preset elongation difference values and interval correction coefficients, when the judgment result shows that the finished round steel is unqualified, the resilience is overlarge and the elongation is insufficient, the elongation difference value between the actual elongation and the preset elongation is calculated, and the corresponding correction coefficient is selected according to the comparison result of the elongation difference value and the preset elongation difference value to correct the interval of the rollers, so that the control precision of the rolling process is further improved, and the quality of the rolled steel bar is further improved.

Drawings

Fig. 1 is a flow chart of the HRB600 high-strength aseismic steel bar rolling process of the present invention.

Detailed Description

In order that the objects and advantages of the invention will be more clearly understood, the invention is further described below with reference to examples; it should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Preferred embodiments of the present invention are described below with reference to the accompanying drawings. It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and do not limit the scope of the present invention.

It should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "upper", "lower", "left", "right", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, which are only for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Fig. 1 is a flow chart of a rolling process of the HRB600 high-strength anti-seismic steel bar according to the present invention.

The HRB600 high-strength anti-seismic steel bar rolling process provided by the embodiment of the invention comprises the following steps:

s1, the control module controls to convey the steel billet to the heating furnace through the conveying roller to be heated to a first preset temperature T1, and conveys the steel billet to the roughing mill to be roughly rolled when the heating is finished, so that roughly rolled round steel is obtained;

step S2, when rough rolling is completed, the obtaining module obtains the diameter D of the rough-rolled steel bar detected by the first laser diameter gauge, and when the rough-rolled steel bar is determined to be completed, the rough-rolled steel bar is cooled to a preset temperature range Ty through a water cooling tank;

step S3, the control module controls the roll spacing of a driving roll and a driven roll of a finishing mill roll to be determined according to the diameter D, and the roughly rolled round steel after being cooled is conveyed to a finishing mill to be finish rolled to obtain finish rolled ribbed round steel;

s4, conveying the finish-rolled ribbed round steel subjected to finish rolling to a shearing machine by a control module, shearing and naturally cooling to obtain the HRB600 high-strength anti-seismic steel bar;

in the step S3, the obtaining module obtains a pre-finish rolling temperature Tq of the rough rolled round steel detected by the first temperature sensor disposed above the conveying roller, obtains a finish rolling temperature Tz detected by the second temperature sensor disposed after the third finishing mill when the finish rolled round steel exits the third finishing mill, and obtains a diameter of the finish rolled round steel detected by the second laser diameter gauge, and the control module analyzes and determines whether the finish rolled round steel is qualified or not according to the diameter Dj of the finish rolled round steel, and adjusts parameters of the heating furnace, the rough rolling mill, and the finishing mill according to an analysis result when the finish rolled round steel is unqualified.

Specifically, in the step S3, when the control module determines the roller spacing between the driving roller and the driven roller of the front 3 finishing mill rollers according to the diameter D of the rough rolling round steel, the control module compares the diameter D of the rough rolling round steel with the preset diameter of the rough rolling round steel set therein, and determines the roller spacing of the finishing mill rollers according to the comparison result,

wherein the control module is provided with a first preset rough rolling round steel diameter D1, a second preset rough rolling round steel diameter D2, a third preset rough rolling round steel diameter D3, a first roller spacing H1, a second roller spacing H2 and a third roller spacing H3, wherein D1 is more than D2 and more than D3, H1 is more than H2 and more than H3,

when D is not more than D1, the control module determines that the roller spacing between the driving roller and the driven roller of the finishing mill roller is a first roller spacing H1;

when D1 is more than D and less than or equal to D2, the control module determines the roll spacing between the driving roll and the driven roll of the finishing mill roll to be a second roll spacing H2;

and when D2 is more than or equal to D3, the control module determines the roll spacing between the driving roll and the driven roll of the finishing mill roll to be the third roll spacing H3.

Specifically, in the step S3, when the rough rolled round bar is finish rolled, the control module analyzes and determines whether the finish rolled round bar is qualified according to the diameter Dj of the finish rolled round bar, the control module calculates the resilience W of the finish rolled round bar according to the diameter Dj of the finish rolled round bar and the roll inner diameter U of the 3 rd finishing mill, preliminarily determines whether the finish rolled round bar is qualified according to a comparison result between the resilience W and a preset resilience range W0, and the preset resilience range W0 includes a minimum resilience Wmin and a maximum resilience Wmax,

if W belongs to W0, the control module preliminarily judges that the finish rolled round steel is qualified;

if W is larger than Wmax, the control module preliminarily judges that the finish rolling round steel is unqualified;

and if W is less than Wmin, the control module judges that the finish rolled round steel is unqualified.

Specifically, when the control module preliminarily determines that the finish rolled round steel is qualified, the control module acquires the elongation P of the finish rolled round steel finish-rolled by the first three finish rolling mills, compares the elongation P with a preset elongation P0, and determines whether the finish rolled round steel is qualified according to the comparison result,

if the P is larger than or equal to P0, the control module judges that the finish rolling round steel is qualified;

and if P is less than P0, the control module judges that the finish rolled round steel is unqualified.

Specifically, when the control module preliminarily judges that the finish rolled round steel is unqualified, the control module calculates a first springback difference value delta Wa between the springback value W and a preset maximum springback value Wmax, sets delta W to be W-Wmax, selects a corresponding interval adjusting coefficient according to a comparison result of the springback difference value and the preset springback difference value to adjust the roller interval,

wherein the control module is also provided with a first preset springback difference value delta W1, a second springback difference value delta W2, a third springback difference value delta W3, a first interval adjusting coefficient K1, a second interval adjusting coefficient K2 and a third interval adjusting coefficient K3, wherein delta W1 is more than delta W2 is more than delta W3, 0.5 is more than K3 is more than K2 is more than K1 is more than 1,

when the delta Wa is not more than delta W1, the control module selects a first spacing adjustment coefficient K1 to adjust the roller spacing;

when the delta W1 is larger than the delta Wa and is smaller than or equal to the delta W2, the control module selects a second spacing adjustment coefficient K2 to adjust the roller spacing;

when the delta W2 is larger than the delta Wa and is not larger than the delta W3, the control module selects a third distance adjusting coefficient K3 to adjust the roller distance;

when the control module selects the ith interval adjusting coefficient Ki to adjust the roller interval, setting i to be 1, 2 and 3, and setting the adjusted roller interval to be Hk by the control module, setting Hk to be Hn multiplied by Ki and n to be 1, 2 and 3.

Specifically, when the control module judges that the finish rolled round steel is unqualified and W is less than Wmin, the control module calculates a second difference value delta Wb between the springback quantity W and the preset minimum springback quantity Wmin, sets delta W to Wmin-W, selects a corresponding temperature regulating coefficient according to a comparison result of the second difference value and the preset difference value to regulate the first preset temperature T1,

wherein the control module is also provided with a first temperature regulating coefficient Kt1, a second temperature regulating coefficient Kt2 and a third temperature regulating coefficient Kt3, the setting is that Kt3 is more than 0.5 and more than Kt2 and more than Kt1 is less than 2,

when the delta Wb is less than or equal to the delta W1, the control module selects a first temperature adjusting coefficient Kt1 to adjust a first preset temperature T1;

when the delta W is more than or equal to delta W1 and the delta Wb is more than or equal to delta W2, the control module selects a second temperature adjusting coefficient Kt2 to adjust the first preset temperature T1;

when the delta W is more than or equal to delta W2 and the delta Wb is more than or equal to delta W3, the control module selects a third temperature adjusting coefficient Kt3 to adjust the first preset temperature T1;

when the control module selects the ith temperature adjustment coefficient Ktr to adjust the first preset temperature T1, r is set to 1, 2, and 3, the control module sets the adjusted first preset temperature to T1, and sets T2 to T1 × Ktr.

Specifically, when the control module determines that the round bar is not qualified and that P is less than P0, the control module calculates a finishing temperature difference Δ Ta between the pre-finishing temperature Tq and a finishing temperature Tz detected by a second temperature sensor, sets Δ Ta to Tq-Tz, and determines whether to adjust the frequency of the high-frequency generator after the third finishing mill according to a comparison result between the finishing temperature difference and a preset finishing temperature difference Δ Ta0,

if Δ Ta > Δ Ta0, the control module determines to adjust the frequency of the high frequency generator;

if Δ Ta is less than or equal to Δ Ta0, the control module determines not to adjust the frequency of the high frequency generator.

Specifically, when the control module determines to adjust the frequency of the high-frequency generator, the control module calculates an elongation difference Δ P between the elongation P and a preset elongation P0, sets Δ P to P0-P, selects a corresponding frequency adjustment coefficient according to a comparison result between the elongation difference and the preset elongation difference for adjustment,

wherein the control module is further provided with a first preset elongation difference value delta P1, a second preset elongation difference value delta P2, a third preset elongation difference value delta P3, a first frequency adjusting coefficient Kp1, a second frequency adjusting coefficient Kp2 and a third frequency adjusting coefficient Kp3, wherein delta P1 is more than delta P2 is more than delta P3, 1 Kp1 is more than 1 Kp2 is more than 1 Kp3 is less than 1.5,

when the delta P is less than or equal to the delta P1, the control module selects a first frequency adjusting coefficient Kp1 to adjust the frequency of the high-frequency generator;

when the delta P is more than or equal to delta P1 and less than or equal to delta P2, the control module selects a second frequency adjusting coefficient Kp2 to adjust the frequency of the high-frequency generator;

when the delta P is more than or equal to delta P2 and less than or equal to delta P3, the control module selects a third frequency adjusting coefficient Kp3 to adjust the frequency of the high-frequency generator;

when the control module selects the e-th frequency adjustment coefficient Kpe to adjust the frequency of the high-frequency generator, the control module sets the adjusted frequency of the high-frequency generator to Pk, the Pk is set to Pm multiplied by Kpe, and Pm is the initial frequency of the high-frequency generator.

Specifically, when the control module finishes the frequency adjustment of the high-frequency generator, the control module selects a corresponding distance correction coefficient according to the comparison result of the elongation difference and a preset elongation difference to correct the roller distance,

wherein the control module is also provided with a first pitch correction coefficient X1, a second pitch correction coefficient X2 and a third pitch correction coefficient X3, wherein the setting is 0.7 < X3 < X2 < X1 < 1,

when the delta P is less than or equal to the delta P1, the control module selects a first pitch correction coefficient X1 to correct the roller pitch;

when the delta P is more than or equal to delta P1 and less than or equal to delta P2, the control module selects a second pitch correction coefficient X2 to correct the roll pitch;

when the delta P is more than or equal to delta P2 and less than or equal to delta P3, the control module selects a third pitch correction coefficient X3 to correct the roller pitch;

when the control module selects the s-th pitch correction coefficient Xs to correct the roller pitch, s is set to be 1, 2 and 3, and the control module sets the corrected roller pitch to be Hx which is set to be Hk multiplied by Xs.

Specifically, in the step S3, the control module determines the initial frequency of the high-frequency generator based on the comparison of the pre-finish rolling temperature Tq and a preset pre-finish rolling temperature,

wherein the control module is also provided with a first preset temperature Tq1 before finish rolling, a second preset temperature Tq2 before finish rolling, a third preset temperature Tq3 before finish rolling, a first initial frequency P1, a second initial frequency P2 and a third initial frequency P3, wherein Tq1 is more than Tq2 and more than Tq3, P1 is more than P2 and more than P3,

when Tq is not greater than Tq1, the control module sets the initial frequency of the high-frequency generator to a first initial frequency P1;

when Tq1 < Tq ≦ Tq2, the control module sets the initial frequency of the high frequency generator to a second initial frequency P2;

when Tq2 < Tq ≦ Tq3, the control module sets the initial frequency of the high frequency generator to a third initial frequency P3.

So far, the technical solutions of the present invention have been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Equivalent changes or substitutions of related technical features can be made by those skilled in the art without departing from the principle of the invention, and the technical scheme after the changes or substitutions can fall into the protection scope of the invention.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention; various modifications and alterations to this invention will become apparent to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A HRB600 high-strength anti-seismic steel bar rolling process is characterized by comprising the following steps:

s1, the control module controls to convey the steel billet to the heating furnace through the conveying roller to be heated to a first preset temperature T1, and conveys the steel billet to the roughing mill to be roughly rolled when the heating is finished, so that roughly rolled round steel is obtained;

step S2, when rough rolling is completed, the obtaining module obtains the diameter D of the rough-rolled steel bar detected by the first laser diameter gauge, and when the rough-rolled steel bar is determined to be completed, the rough-rolled steel bar is cooled to a preset temperature range Ty through a water cooling tank;

step S3, the control module controls the roll spacing of a driving roll and a driven roll of a finishing mill roll to be determined according to the diameter D, and the roughly rolled round steel after being cooled is conveyed to a finishing mill to be finish rolled to obtain finish rolled ribbed round steel;

s4, conveying the finish-rolled ribbed round steel subjected to finish rolling to a shearing machine by a control module, shearing and naturally cooling to obtain the HRB600 high-strength anti-seismic steel bar;

in the step S3, the obtaining module obtains a pre-finish rolling temperature Tq of the rough rolled round steel detected by the first temperature sensor disposed above the conveying roller, obtains a finish rolling temperature Tz detected by the second temperature sensor disposed after the third finishing mill when the finish rolled round steel exits the third finishing mill, and obtains a diameter of the finish rolled round steel detected by the second laser diameter gauge, and the control module analyzes and determines whether the finish rolled round steel is qualified or not according to the diameter Dj of the finish rolled round steel, and adjusts parameters of the heating furnace, the rough rolling mill, and the finishing mill according to an analysis result when the finish rolled round steel is unqualified.

2. The HRB600 high-strength anti-seismic steel bar rolling process according to claim 1, wherein in the step S3, when the control module determines the roller spacing between the driving roller and the driven roller of the front 3 frames of finishing mill rollers according to the diameter D of the rough rolling round steel, the control module compares the diameter D of the rough rolling round steel with the preset diameter of the rough rolling round steel arranged therein and determines the roller spacing of the finishing mill rollers according to the comparison result,

wherein the control module is provided with a first preset rough rolling round steel diameter D1, a second preset rough rolling round steel diameter D2, a third preset rough rolling round steel diameter D3, a first roller spacing H1, a second roller spacing H2 and a third roller spacing H3, wherein D1 is more than D2 and more than D3, H1 is more than H2 and more than H3,

when D is not more than D1, the control module determines that the roller spacing between the driving roller and the driven roller of the finishing mill roller is a first roller spacing H1;

when D1 is more than D and less than or equal to D2, the control module determines the roll spacing between the driving roll and the driven roll of the finishing mill roll to be a second roll spacing H2;

and when D2 is more than or equal to D3, the control module determines the roll spacing between the driving roll and the driven roll of the finishing mill roll to be the third roll spacing H3.

3. The HRB600 high-strength aseismic reinforcement rolling process of claim 2, wherein in the step S3, when the rough rolled round bar is finish rolled, the control module analyzes and determines whether the finish rolled round bar is qualified according to the diameter Dj of the finish rolled round bar, calculates the resilience W of the finish rolled round bar according to the diameter Dj of the finish rolled round bar and the roll inner diameter U of the 3 rd finishing mill, preliminarily determines whether the finish rolled round bar is qualified according to the comparison result between the resilience W and a preset resilience range W0, the preset resilience range W0 includes a preset minimum resilience Wmin and a preset maximum resilience Wmax,

if W belongs to W0, the control module preliminarily judges that the finish rolled round steel is qualified;

if W is larger than Wmax, the control module preliminarily judges that the finish rolling round steel is unqualified;

and if W is less than Wmin, the control module judges that the finish rolled round steel is unqualified.

4. The HRB600 high-strength aseismic reinforcement rolling process according to claim 3, wherein when the control module preliminarily determines that the finish rolled round steel is qualified, the control module obtains the elongation P of the finish rolled round steel finished by the first three finish rolling mills, compares the elongation P with a preset elongation P0, and determines whether the finish rolled round steel is qualified according to the comparison result,

if the P is larger than or equal to P0, the control module judges that the finish rolling round steel is qualified;

and if P is less than P0, the control module judges that the finish rolled round steel is unqualified.

5. The HRB600 high-strength anti-seismic steel bar rolling process according to claim 4, wherein when the control module preliminarily determines that the finish rolled round steel bar is unqualified, the control module calculates a first springback difference value Δ Wa between the springback W and a preset maximum springback Wmax, sets the Δ W to W-Wmax, selects a corresponding distance adjustment coefficient according to a comparison result of the springback difference value and the preset springback difference value to adjust the roller distance,

wherein the control module is also provided with a first preset springback difference value delta W1, a second springback difference value delta W2, a third springback difference value delta W3, a first interval adjusting coefficient K1, a second interval adjusting coefficient K2 and a third interval adjusting coefficient K3, wherein delta W1 is more than delta W2 is more than delta W3, 0.5 is more than K3 is more than K2 is more than K1 is more than 1,

when the delta Wa is not more than delta W1, the control module selects a first spacing adjustment coefficient K1 to adjust the roller spacing;

when the delta W1 is larger than the delta Wa and is smaller than or equal to the delta W2, the control module selects a second spacing adjustment coefficient K2 to adjust the roller spacing;

when the delta W2 is larger than the delta Wa and is not larger than the delta W3, the control module selects a third distance adjusting coefficient K3 to adjust the roller distance;

when the control module selects the ith interval adjusting coefficient Ki to adjust the roller interval, setting i to be 1, 2 and 3, and setting the adjusted roller interval to be Hk by the control module, setting Hk to be Hn multiplied by Ki and n to be 1, 2 and 3.

6. The HRB600 high-strength anti-seismic steel bar rolling process according to claim 5, wherein when the control module determines that the finish rolled round steel bar is unqualified and W is less than Wmin, the control module calculates a second difference Δ Wb between the springback W and a preset minimum springback Wmin, sets Δ W to Wmin-W, selects a corresponding temperature adjustment coefficient according to the comparison result of the second difference Δ Wb and the preset difference Δ Wmin to adjust the first preset temperature T1,

wherein the control module is also provided with a first temperature regulating coefficient Kt1, a second temperature regulating coefficient Kt2 and a third temperature regulating coefficient Kt3, the setting is that Kt3 is more than 0.5 and more than Kt2 and more than Kt1 is less than 2,

when the delta Wb is less than or equal to the delta W1, the control module selects a first temperature adjusting coefficient Kt1 to adjust a first preset temperature T1;

when the delta W is more than or equal to delta W1 and the delta Wb is more than or equal to delta W2, the control module selects a second temperature adjusting coefficient Kt2 to adjust the first preset temperature T1;

when the delta W is more than or equal to delta W2 and the delta Wb is more than or equal to delta W3, the control module selects a third temperature adjusting coefficient Kt3 to adjust the first preset temperature T1;

when the control module selects the ith temperature adjustment coefficient Ktr to adjust the first preset temperature T1, r is set to 1, 2, and 3, the control module sets the adjusted first preset temperature to T1, and sets T2 to T1 × Ktr.

7. The HRB600 high-strength aseismic reinforcement rolling process according to claim 6, wherein when the control module determines that the finish rolled round bar is not qualified and P is less than P0, the control module calculates a finish rolling temperature difference Δ Ta between the temperature Tq before finish rolling and the finish rolling temperature Tz detected by the second temperature sensor, sets Δ Ta-Tz, and determines whether to adjust the frequency of the high frequency generator after the third finish rolling according to a comparison result between the finish rolling temperature difference and a preset finish rolling temperature difference Δ Ta0,

if Δ Ta > Δ Ta0, the control module determines to adjust the frequency of the high frequency generator;

if Δ Ta is less than or equal to Δ Ta0, the control module determines not to adjust the frequency of the high frequency generator.

8. The HRB600 high-strength anti-seismic steel bar rolling process according to claim 7, wherein when the control module determines to adjust the frequency of the high-frequency generator, the control module calculates an elongation difference Δ P between the elongation P and a preset elongation P0, sets the elongation difference Δ P to P0-P, selects a corresponding frequency adjustment coefficient according to the comparison result between the elongation difference and the preset elongation difference for adjustment,

wherein the control module is further provided with a first preset elongation difference value delta P1, a second preset elongation difference value delta P2, a third preset elongation difference value delta P3, a first frequency adjusting coefficient Kp1, a second frequency adjusting coefficient Kp2 and a third frequency adjusting coefficient Kp3, wherein delta P1 is more than delta P2 is more than delta P3, 1 Kp1 is more than 1 Kp2 is more than 1 Kp3 is less than 1.5,

when the delta P is less than or equal to the delta P1, the control module selects a first frequency adjusting coefficient Kp1 to adjust the frequency of the high-frequency generator;

when the delta P is more than or equal to delta P1 and less than or equal to delta P2, the control module selects a second frequency adjusting coefficient Kp2 to adjust the frequency of the high-frequency generator;

when the delta P is more than or equal to delta P2 and less than or equal to delta P3, the control module selects a third frequency adjusting coefficient Kp3 to adjust the frequency of the high-frequency generator;

when the control module selects the e-th frequency adjustment coefficient Kpe to adjust the frequency of the high-frequency generator, the control module sets the adjusted frequency of the high-frequency generator to Pk, the Pk is set to Pm multiplied by Kpe, and Pm is the initial frequency of the high-frequency generator.

9. The HRB600 high-strength anti-seismic steel bar rolling process according to claim 8, wherein when the control module completes the frequency adjustment of the high frequency generator, the control module selects a corresponding distance correction coefficient to correct the roller distance according to the comparison result of the elongation difference and a preset elongation difference,

wherein the control module is also provided with a first pitch correction coefficient X1, a second pitch correction coefficient X2 and a third pitch correction coefficient X3, wherein the setting is 0.7 < X3 < X2 < X1 < 1,

when the delta P is less than or equal to the delta P1, the control module selects a first pitch correction coefficient X1 to correct the roller pitch;

when the delta P is more than or equal to delta P1 and less than or equal to delta P2, the control module selects a second pitch correction coefficient X2 to correct the roll pitch;

when the delta P is more than or equal to delta P2 and less than or equal to delta P3, the control module selects a third pitch correction coefficient X3 to correct the roller pitch;

when the control module selects the s-th pitch correction coefficient Xs to correct the roller pitch, s is set to be 1, 2 and 3, and the control module sets the corrected roller pitch to be Hx which is set to be Hk multiplied by Xs.

10. The HRB600 high-strength aseismic reinforcement rolling process of claim 9, wherein in the step S3, the control module determines the initial frequency of the high frequency generator according to the comparison of the pre-finish rolling temperature Tq and a preset pre-finish rolling temperature,

wherein the control module is also provided with a first preset temperature Tq1 before finish rolling, a second preset temperature Tq2 before finish rolling, a third preset temperature Tq3 before finish rolling, a first initial frequency P1, a second initial frequency P2 and a third initial frequency P3, wherein Tq1 is more than Tq2 and more than Tq3, P1 is more than P2 and more than P3,

when Tq is not greater than Tq1, the control module sets the initial frequency of the high-frequency generator to a first initial frequency P1;

when Tq1 < Tq ≦ Tq2, the control module sets the initial frequency of the high frequency generator to a second initial frequency P2;

when Tq2 < Tq ≦ Tq3, the control module sets the initial frequency of the high frequency generator to a third initial frequency P3.

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