CN114182169A - 一种厚壁大口径x80m级热煨弯管用板及其制造方法 - Google Patents

一种厚壁大口径x80m级热煨弯管用板及其制造方法 Download PDF

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CN114182169A
CN114182169A CN202111385420.2A CN202111385420A CN114182169A CN 114182169 A CN114182169 A CN 114182169A CN 202111385420 A CN202111385420 A CN 202111385420A CN 114182169 A CN114182169 A CN 114182169A
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官英平
姜金星
王青峰
谯明亮
翟冬雨
段永川
吴俊平
杜海军
袁良增
杨志瀚
刘帅
赵丽洋
史根豪
殷杰
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Yanshan University
Nanjing Iron and Steel Co Ltd
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Abstract

本发明公开了一种厚壁大口径X80M级热煨弯管用板及其制造方法,涉及钢铁生产技术领域,其化学成分及质量百分比如下:C:0.05%~0.15%,Si:0.10%~0.40%,Mn:1.50%~1.80%,P≤0.015%,S≤0.0050%,Nb:0.030%~0.080%,V≤0.060%,Ti≤0.040%,Cr≤0.40%,Ni:0.20%~1.00%,Mo:0.15%~0.50%,Cu≤0.35%,Al:0.015%~0.050%,Ca:0.0005%~0.0040%,B≤0.0005%,N≤0.0050%,余量为Fe和不可避免的杂质。采用了微合金化近包晶成分设计、纯净钢冶炼技术,通过轧制冷却工艺,得到少量先共析铁素体、针状铁素体、粒状贝氏体多相复合组织,满足了产品低温韧性和高强度的要求,满足了后续热煨弯管的使用要求。

Description

一种厚壁大口径X80M级热煨弯管用板及其制造方法
技术领域
本发明涉及钢铁生产技术领域,特别是涉及一种厚壁大口径X80M级热煨弯管用板及其制造方法。
背景技术
随着我国天然气工业的高速发展和石油、天然气等资源需求的日益增长,输送效率进一步提高,管道输送正向大口径、大壁厚和高压输送方向发展。中俄东线天然气管道工程,全长3371公里,是我国目前口径最大、压力最高的长距离天然气输送管道,干线线路管径1422mm,设计压力12MPa,设计输量380×108m3/a。中俄东线北段(黑河—长岭)的部分地段热煨弯管管道采用φ1422×33.8mm规格X80管线钢,强韧性要求高。长距离天然气管道建设采用高压、大直径、厚壁的方式,以降低天然气管道建设和运营成本,提高其输送效率,要求更为优良的低温冲击韧性(-45℃KV2≥200J)适用于更恶劣的服役环境。
厚壁大口径热煨弯管用板X80管线钢研制的技术关键是如何同时保证产品的高强度和良好的低温韧性以及热煨弯管的调质性能。中俄东线大口径厚壁低温热煨弯管(φ1422×(≥)30mm规格X80(适用温度-45℃))用板研制难度大,主要采用控轧控冷、微合金化近包晶成分设计技术。钢板制成管后性能会下降,为确保弯管最终的强度和低温韧性达到设计要求,需提高钢的“淬透性”,以保证得到强韧匹配优异的中低温转变组织。又由于X80管线钢宽厚板压缩比有限,如何优化关键合金成分和TMCP工艺,以获得数量较多、细化的大角度晶界及亚结构,从而调控优异的-45℃低温韧性的管线钢板,是目前要解决的难题。
发明内容
本发明针对上述技术问题,克服现有技术的缺点,提供一种厚壁大口径X80M级热煨弯管用板,其化学成分及质量百分比如下:C:0.05%~0.15%,Si:0.10%~0.40%,Mn:1.50%~1.80%,P≤0.015%,S≤0.0050%,Nb:0.030%~0.080%,V≤0.060%,Ti≤0.040%,Cr≤0.40%,Ni:0.20%~1.00%,Mo:0.15%~0.50%,Cu≤0.35%,Al:0.015%~0.050%,Ca:0.0005%~0.0040%,B≤0.0005%,N≤0.0050%,余量为Fe和不可避免的杂质。
本发明进一步限定的技术方案是:
前所述的一种厚壁大口径X80M级热煨弯管用板,其化学成分及质量百分比如下:C:0.05%~0.10%,Si:0.10%~0.30%,Mn:1.50%~1.70%,P≤0.013%,S≤0.0020%,Nb:0.030%~0.060%,V≤0.060%,Ti≤0.040%,Cr≤0.40%,Ni:0.20%~0.60%,Mo:0.15%~0.30%,Cu≤0.35%,Al:0.015%~0.040%,Ca:0.0005%~0.0030%,B≤0.0005%,N≤0.0050%,余量为Fe和不可避免的杂质。
前所述的一种厚壁大口径X80M级热煨弯管用板,其化学成分及质量百分比如下:C:0.06%~0.11%,Si:0.20%~0.40%,Mn:1.60%~1.80%,P≤0.013%,S≤0.0050%,Nb:0.050%~0.080%,V≤0.060%,Ti≤0.040%,Cr≤0.40%,Ni:0.40%~0.70%,Mo:0.20%~0.40%,Cu≤0.35%,Al:0.020%~0.050%,Ca:0.0008%~0.0040%,B≤0.0005%,N≤0.0050%,余量为Fe和不可避免的杂质。
前所述的一种厚壁大口径X80M级热煨弯管用板,其化学成分及质量百分比如下:C:0.07%~0.12%,Si:0.15%~0.35%,Mn:1.60%~1.70%,P≤0.013%,S≤0.0030%,Nb:0.040%~0.070%,V≤0.060%,Ti:0.006~0.040%,Cr:0.10~0.40%,Ni:0.30%~0.70%,Mo:0.20%~0.35%,Cu≤0.35%,Al:0.020%~0.040%,Ca:0.0008%~0.0035%,B≤0.0005%,N≤0.0050%,余量为Fe和不可避免的杂质。
本发明的另一目的在于提供一种厚壁大口径X80M级热煨弯管用板制造方法,包括以下步骤:
S1、采用顶底复吹转炉冶炼,实现低碳、低磷硫出钢,LF+RH精炼进行升温、造渣、脱硫、夹杂物球化、去气去夹杂操作,浇铸得到成分均匀、内部组织优异的合格铸坯;
S2、铸坯表检合格到步进式加热炉进行奥氏体化加热,采用数字脉冲火焰控制及二级计算机燃烧控制,奥氏体化温度1160~1180℃,温度均匀性≤10℃;
S3、采用两阶段轧制技术进行铸坯轧制,第一阶段轧制开轧温度1030~1060℃,第二阶段轧制温度820~850℃,终轧温度770~800℃,入水温度740~760℃,返红温度400~450℃。
前所述的一种厚壁大口径X80M级热煨弯管用板制造方法,步骤S1,通过260mm~320mm断面弧形连铸机浇铸。
本发明的有益效果是:
(1)本发明通过研究高强厚板微结构形态与低温韧性之间的关系,分析数量多而细化的大角度晶界和细匀分布的M/A等复相组织微结构对低温韧性的调控机理,构建新的强韧化机理,从而解决综合力学性能调控的关键技术问题,突破厚壁大口径低温热煨弯管X80高强高韧的技术瓶颈,形成稳定批量生产的全流程生产技术,为实现工业规模生产及应用奠定基础;
(2)本发明中高锰基础上适量控制Ni/Mo/Nb元素含量,通过合理的控轧控冷工艺,保证了宽厚规格X80M获得均匀细化的少量先共析铁素体、针状铁素体、粒状贝氏体多相复合组织,在保证高强度和低温韧性的同时,获得热煨后优异的调质性能;
(3)本发明中BOF+LF+RH冶炼工艺,有效提升了钢水洁净度,降低了钢板的其它含量,获得了洁净度满足高钢级管线产品的优质铸坯;
(4)本发明中低温奥氏体化技术是充分依据合金的熔化原理,保证了Ni、Mo、Nb等合金元素固溶强化作用,也达到了降低原始奥氏体化晶粒度的作用,提升了产品的低温韧性及制管形变能力;
(5)本发明根据产品规格及成分设计的轧制冷却温度,得到少量先共析铁素体+针状铁素体+粒状贝氏体的多相细匀组织,实现了产品厚度方向上的组织均匀性,在保证高强度的同时,实现低温冲击韧性-45℃的KV2≥200J性能。
附图说明
图1为本发明实施例1的金相组织图。
具体实施方式
实施例1
本实施例提供的一种厚壁大口径X80M级热煨弯管用板,其化学成分及质量百分比如下:C:0.058%,Si:0.18%,Mn:1.65%,P:0.011%,S:0.0012%,Nb:0.039%,V:0.010%,Ti:0.019%,Cr:0.03%,Ni:0.39%,Mo:0.19%,Cu:0.03%,Al:0.029%,Ca:0.0019%,B:0.0003%,N:0.0031%,余量为Fe和不可避免的杂质。
其制造方法包括以下步骤:
S1、采用顶底复吹转炉冶炼,实现低碳、低磷硫出钢,LF+RH精炼进行升温、造渣、脱硫、夹杂物球化、去气去夹杂操作,通过320mm断面弧形连铸机浇铸,得到成分均匀、内部组织优异的合格铸坯;
S2、铸坯表检合格到步进式加热炉进行奥氏体化加热,采用数字脉冲火焰控制及二级计算机燃烧控制,奥氏体化温度1169℃,温度均匀性6℃;
S3、采用两阶段轧制技术进行铸坯轧制,第一阶段轧制开轧温度1039℃,第二阶段轧制温度836℃,终轧温度789℃,入水温度755℃,返红温度436℃。
实施例2
本实施例提供的一种厚壁大口径X80M级热煨弯管用板及其制造方法,其化学成分及质量百分比如下:C:0.10%,Si:0.33%,Mn:1.69%,P:0.010%,S:0.0010%,Nb:0.073%,V:0.020%,Ti:0.013%,Cr:0.03%,Ni:0.62%,Mo:0.33%,Cu:0.03%,Al:0.029%,Ca:0.0017%,B:0.0001%,N:0.0029%,余量为Fe和不可避免的杂质。
其制造方法包括以下步骤:
S1、采用顶底复吹转炉冶炼,实现低碳、低磷硫出钢,LF+RH精炼进行升温、造渣、脱硫、夹杂物球化、去气去夹杂操作,通过260mm断面弧形连铸机浇铸,得到成分均匀、内部组织优异的合格铸坯;
S2、铸坯表检合格到步进式加热炉进行奥氏体化加热,采用数字脉冲火焰控制及二级计算机燃烧控制,奥氏体化温度1178℃,温度均匀性5℃;
S3、采用两阶段轧制技术进行铸坯轧制,第一阶段轧制开轧温度1056℃,第二阶段轧制温度829℃,终轧温度778℃,入水温度749℃,返红温度421℃。
实施例3
本实施例提供的一种厚壁大口径X80M级热煨弯管用板及其制造方法,其化学成分及质量百分比如下:C:0.09%,Si:0.30%,Mn:1.67%,P:0.012%,S:0.0013%,Nb:0.055%,V:0.010%,Ti:0.015%,Cr:0.13%,Ni:0.56%,Mo:0.31%,Cu:0.03%,Al:0.036%,Ca:0.0019%,B:0.0002%,N:0.0038%,余量为Fe和不可避免的杂质。
其制造方法包括以下步骤:
S1、采用顶底复吹转炉冶炼,实现低碳、低磷硫出钢,LF+RH精炼进行升温、造渣、脱硫、夹杂物球化、去气去夹杂操作,通过320mm断面弧形连铸机浇铸,得到成分均匀、内部组织优异的合格铸坯;
S2、铸坯表检合格到步进式加热炉进行奥氏体化加热,采用数字脉冲火焰控制及二级计算机燃烧控制,奥氏体化温度1169℃,温度均匀性不大于3℃;
S3、采用二阶段轧制技术进行铸坯轧制,第一阶段轧制开轧温度1059℃,二阶段轧制温度842℃,终轧温度796℃,入水温度756℃,返红温度436℃。
实施例1、实施例2、实施例3产品的力学性能测试结果如下表:
实施例 Y.S(MPa) T.S(MPS) A% 屈强比 横向冲击均值(-45℃)
实施例1 563 698 38 81 365
实施例2 559 715 37 78 385
实施例3 589 730 36 81 392
综上所述,本发明采用近包晶碳设计,提高钢板的低温韧性和可焊性的同时,保证钢板制管变形后的组织稳定性和热煨弯管制作过程中的调质性能;采用高锰设计,提高产品强度,有效细化组织;采用镍、钼、铌设计,配合控轧控冷工艺,保证宽厚规格X80M级钢板获得均匀细化的少量先共析铁素体、针状铁素体、粒状贝氏体多相复合组织,在保证高强韧性的同时获得热煨后良好的调质性能。
除上述实施例外,本发明还可以有其他实施方式。凡采用等同替换或等效变换形成的技术方案,均落在本发明要求的保护范围。

Claims (6)

1.一种厚壁大口径X80M级热煨弯管用板,其特征在于:其化学成分及质量百分比如下:C:0.05%~0.15%,Si:0.10%~0.40%,Mn:1.50%~1.80%,P≤0.015%,S≤0.0050%,Nb:0.030%~0.080%,V≤0.060%,Ti≤0.040%,Cr≤0.40%,Ni:0.20%~1.00%,Mo:0.15%~0.50%,Cu≤0.35%,Al:0.015%~0.050%,Ca:0.0005%~0.0040%,B≤0.0005%,N≤0.0050%,余量为Fe和不可避免的杂质。
2.根据权利要求1所述的一种厚壁大口径X80M级热煨弯管用板,其特征在于:其化学成分及质量百分比如下:C:0.05%~0.10%,Si:0.10%~0.30%,Mn:1.50%~1.70%,P≤0.013%,S≤0.0020%,Nb:0.030%~0.060%,V≤0.060%,Ti≤0.040%,Cr≤0.40%,Ni:0.20%~0.60%,Mo:0.15%~0.30%,Cu≤0.35%,Al:0.015%~0.040%,Ca:0.0005%~0.0030%,B≤0.0005%,N≤0.0050%,余量为Fe和不可避免的杂质。
3.根据权利要求1所述的一种厚壁大口径X80M级热煨弯管用板,其特征在于:其化学成分及质量百分比如下:C:0.06%~0.11%,Si:0.20%~0.40%,Mn:1.60%~1.80%,P≤0.013%,S≤0.0050%,Nb:0.050%~0.080%,V≤0.060%,Ti≤0.040%,Cr≤0.40%,Ni:0.40%~0.70%,Mo:0.20%~0.40%,Cu≤0.35%,Al:0.020%~0.050%,Ca:0.0008%~0.0040%,B≤0.0005%,N≤0.0050%,余量为Fe和不可避免的杂质。
4.根据权利要求1所述的一种厚壁大口径X80M级热煨弯管用板,其特征在于:其化学成分及质量百分比如下:C:0.07%~0.12%,Si:0.15%~0.35%,Mn:1.60%~1.70%,P≤0.013%,S≤0.0030%,Nb:0.040%~0.070%,V≤0.060%,Ti:0.006~0.040%,Cr:0.10~0.40%,Ni:0.30%~0.70%,Mo:0.20%~0.35%,Cu≤0.35%,Al:0.020%~0.040%,Ca:0.0008%~0.0035%,B≤0.0005%,N≤0.0050%,余量为Fe和不可避免的杂质。
5.根据权利要求1所述的一种厚壁大口径X80M级热煨弯管用板制造方法,其特征在于:应用于权利要求1-4任意一项,包括以下步骤:
S1、采用顶底复吹转炉冶炼,实现低碳、低磷硫出钢,LF+RH精炼进行升温、造渣、脱硫、夹杂物球化、去气去夹杂操作,浇铸得到成分均匀、内部组织优异的合格铸坯;
S2、铸坯表检合格到步进式加热炉进行奥氏体化加热,采用数字脉冲火焰控制及二级计算机燃烧控制,奥氏体化温度1160~1180℃,温度均匀性≤10℃;
S3、采用两阶段轧制技术进行铸坯轧制,第一阶段轧制开轧温度1030~1060℃,第二阶段轧制温度820~850℃,终轧温度770~800℃,入水温度740~760℃,返红温度400~450℃。
6.根据权利要求1所述的一种厚壁大口径X80M级热煨弯管用板及其制造方法,其特征在于:所述步骤S1,通过260mm~320mm断面弧形连铸机浇铸。
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