会员体验
专利管家(专利管理)
工作空间(专利管理)
风险监控(情报监控)
数据分析(专利分析)
侵权分析(诉讼无效)
联系我们
交流群
官方交流:
QQ群: 891211   
微信请扫码    >>>
现在联系顾问~
热词
    • 2. 发明授权
    • Ultra-high strength, weldable, boron-containing steels with superior toughness
    • 超高强度,可焊接,具有优异韧性的含硼钢
    • US06228183B1
    • 2001-05-08
    • US09123791
    • 1998-07-28
    • Narasimha-Rao V. BangaruJayoung KooMichael J. LutonClifford W. PetersenHiroshi TamehiroHitoshi AsahiTakuya HaraYoshio Terada
    • Narasimha-Rao V. BangaruJayoung KooMichael J. LutonClifford W. PetersenHiroshi TamehiroHitoshi AsahiTakuya HaraYoshio Terada
    • C22C3814
    • C22C38/06C21D1/19C21D8/00C21D2211/002C21D2211/008C22C38/04C22C38/12C22C38/14
    • An ultra-high strength boron-containing steel having a tensile strength of at least about 900 MPa (130 ksi), a toughness as measured by Charpy V-notch impact test at −40° C. (−40° F.) of at least about 120 joules (90 ft-lbs), and a microstructure comprising predominantly fine-grained lower bainite, fine-grained lath martensite, or mixtures thereof, transformed from substantially unrecrystallized austenite grains and comprising iron and specified weight percentages of the additives: carbon, silicon, manganese, copper, nickel, niobium, vanadium, molybdenum, chromium, titanium, aluminum, calcium, Rare Earth Metals, and magnesium, is prepared by heating a steel slab to a suitable temperature; reducing the slab to form plate in one or more hot rolling passes in a first temperature range in which austenite recrystallizes; further reducing said plate in one or more hot rolling passes in a second temperature range below said first temperature range and above the temperature at which austenite begins to transform to ferrite during cooling; quenching said plate to a suitable Quench Stop Temperature; and stopping said quenching and allowing said plate to air cool to ambient temperature.
    • 具有至少约900MPa(130ksi)拉伸强度的超高强度含硼钢,在-40℃(-40°F)下通过夏比V-缺口冲击试验测得的韧性 至少约120焦耳(90ft-lbs),以及由基本上未再结晶的奥氏体晶粒转化并且包含铁和特定重量百分比的添加剂的主要包含细粒度的下贝氏体,细粒状板条马氏体或其混合物的微观结构:碳 通过将钢坯加热到合适的温度来制备硅,锰,铜,镍,铌,钒,钼,铬,钛,​​铝,钙,稀土金属和镁, 在奥氏体重结晶的第一温度范围内,在一个或多个热轧道中将板坯还原成板; 在低于所述第一温度范围的第二温度范围内并且高于在冷却期间奥氏体开始转变为铁素体的温度的一个或多个热轧道中进一步减少所述板; 将所述板淬火至合适的淬火停止温度; 并停止所述淬火并允许所述板空气冷却至环境温度。
    • 6. 发明授权
    • Ultra-high strength, weldable, essentially boron-free steels with superior toughness
    • 超高强度,可焊接,基本上无硼钢,韧性优越
    • US06224689B1
    • 2001-05-01
    • US09123859
    • 1998-07-28
    • Jayoung KooMichael J. LutonNarasimha-Rao V. BangaruClifford W. PetersenHiroshi TamehiroHitoshi AsahiTakuya HaraYoshio Terada
    • Jayoung KooMichael J. LutonNarasimha-Rao V. BangaruClifford W. PetersenHiroshi TamehiroHitoshi AsahiTakuya HaraYoshio Terada
    • C22C3812
    • C22C38/08C21D1/19C21D2211/002C21D2211/005C22C38/04C22C38/12C22C38/14
    • An ultra-high strength essentially boron-free steel having a tensile strength of at least about 900 MPa (130 ksi), a toughness as measured by Charpy V-notch impact test at −40° C. (−40° F.) of at least about 120 joules (90 ft-lbs), and a microstructure comprising predominantly fine-grained lower bainite, fine-grained lath martensite, or mixtures thereof, transformed from substantially unrecrystallized austenite grains and comprising iron and specified weight percentages of the additives: carbon, silicon, manganese, copper, nickel, niobium, vanadium, molybdenum, chromium, titanium, aluminum, calcium, Rare Earth Metals, and magnesium, is prepared by heating a steel slab to a suitable temperature; reducing the slab to form plate in one or more hot rolling passes in a first temperature range in which austenite recrystallizes; further reducing said plate in one or more hot rolling passes in a second temperature range below said first temperature range and above the temperature at which austenite begins to transform to ferrite during cooling; quenching said plate to a suitable Quench Stop Temperature; and stopping said quenching and allowing said plate to air cool to ambient temperature.
    • 具有至少约900MPa(130ksi)拉伸强度的超高强度基本上不含硼的钢,在-40℃(-40°F)下通过夏比V-缺口冲击试验测得的韧性 至少约120焦耳(90ft-lbs),以及由基本上未再结晶的奥氏体晶粒转化并且包含铁和特定重量百分比的添加剂的主要包含细粒度的下贝氏体,细粒状板条马氏体或其混合物的显微组织: 通过将钢坯加热到合适的温度来制备碳,硅,锰,铜,镍,铌,钒,钼,铬,钛,​​铝,钙,稀土金属和镁。 在奥氏体重结晶的第一温度范围内,在一个或多个热轧道中将板坯还原成板; 在低于所述第一温度范围的第二温度范围内并且高于在冷却期间奥氏体开始转变为铁素体的温度的一个或多个热轧道中进一步减少所述板; 将所述板淬火至合适的淬火停止温度; 并停止所述淬火并允许所述板空气冷却至环境温度。
    • 7. 发明授权
    • High strength line pipe steel having low yield ratio and excellent in
low temperature toughness
    • 具有低屈服比,低温韧性优异的高强度线管钢
    • US5755895A
    • 1998-05-26
    • US718567
    • 1996-10-10
    • Hiroshi TamehiroHitoshi AsahiTakuya HaraYoshio Terada
    • Hiroshi TamehiroHitoshi AsahiTakuya HaraYoshio Terada
    • C22C38/04C22C38/44C22C38/48
    • C22C38/04Y10S148/909
    • An ultra-high strength low yield ratio line pipe steel has an excellent HAZ toughness and field weldability and has a tensile strength of at least 950 MPa (exceeding X100 of the API standard). The steel is of a low carbon-high Mn-Ni-Mo-Nb-trace Ti type selectively containing B, Cu, Cr and V, whenever necessary. Its micro-structure comprises a martensite/bainite and ferrite soft/hard two-phase mixed structure having a ferrite fraction of 20 to 90%. This ferrite contains 50 to 1000 of worked ferrite, and the ferrite grain size is not greater than 5 Am. The production of an ultra-high strength low yield ratio line pipe steel (exceeding X100) excellent in low temperature toughness and field weldability becomes possible. As a result, the safety of a pipeline can be remarkably improved, and execution efficiency and transportation efficiency of the pipeline can be drastically improved.
    • PCT No.PCT / JP96 / 00157 Sec。 371日期:1996年10月1日 102(e)日期1996年10月1日PCT 1996年1月26日PCT PCT。 第WO96 / 23909号公报 日期1996年8月8日超高强度低屈服比管线钢具有优异的HAZ韧性和现场焊接性,拉伸强度至少为950MPa(超过API标准的X100)。 该钢是选择性含有B,Cu,Cr和V的低碳高Mn-Ni-Mo-Nb-微量Ti型。 其微结构包括铁素体分数为20〜90%的马氏体/贝氏体和铁素体软/硬两相混合结构。 该铁氧体含有50〜1000个加工铁素体,铁素体晶粒尺寸不大于5A。 可以生产出具有优异的低温韧性和现场焊接性的超高强度低屈服比管线钢管(超过X100)。 因此,可以显着提高管道的安全性,可以显着提高管道的执行效率和运输效率。
    • 10. 发明授权
    • Super-high-strength line pipe excellent in low temperature toughness and production method thereof
    • 低温韧性优异的超高强度线管及其制造方法
    • US06532995B1
    • 2003-03-18
    • US09478653
    • 2000-01-06
    • Hitoshi AsahiHiroshi TamehiroTakuya HaraYoshio TeradaShigeru OhkitaKunio Koyama
    • Hitoshi AsahiHiroshi TamehiroTakuya HaraYoshio TeradaShigeru OhkitaKunio Koyama
    • F16L900
    • C22C38/12C22C38/04C22C38/08C22C38/44C22C38/46C22C38/58Y10T29/18
    • To provide a super-high strength line pipe that is excellent in low temperature toughness, can be field welded easily, and has a tensile strength of at least 900 MPa (exceeding ×100 of the API standard), and a production method thereof. The present invention relates to a super-high strength line pipe produced by shaping a steel plate into a pipe shape and arc welding seam portions, the strength of a base steel portion is 900 to 1,100 MPa and the strength of the weld metal is higher than the base steel strength −100 MPa. In the steel pipe, the Ni content of the weld metal is higher by at least 1% than that of the base steel. The combination of the chemical components of the steel plate with those of the weld metal, for accomplishing these steel pipes by a U&O step is shown concretely. A production method of the steel plate and the welding method for achieving the steel pipe are also described. Furthermore, a method of reducing the strength of the inner surface of the weld metal to restrict cracking at the time of pipe expansion is also shown.
    • 为了提供低温韧性优异的超高强度线管,可以容易地进行现场焊接,并且具有至少900MPa(超过API标准的×100)的拉伸强度及其制造方法。 本发明涉及一种通过将钢板成形为管状和电弧焊缝部而制造的超高强度线管,基部钢的强度为900〜1100MPa,焊接金属的强度高于 基钢强度-100MPa。 在钢管中,焊接金属的Ni含量比基体钢高1%以上。 具体地说,钢板的化学成分与焊接金属的化学成分的组合,通过U&O工序来实现这些钢管。 还描述了钢板的制造方法和用于实现钢管的焊接方法。 此外,还示出了降低焊接金属内表面的强度以限制管膨胀时的开裂的方法。