Effect of inter-cycle heat treatment in accumulative roll-bonding(ARB)process on planar isotropy of mechanical properties of AA1050 sheets

The accumulative roll-bonding(ARB)process was applied on the strips of aluminum alloy 1050 in two processing conditions:cold ARB and warm ARB.The results of tensile tests and microhardness measurement show that the warm ARB process exhibits the lower tensile strength and microhardness,more homogeneous distribution of the microhardness,higher elongation,and especially superior planar isotropy of the tensile properties in comparison to the cold ARB,because of the intermediate heat treatment as well as the elevated temperature rolling in the warm ARB process.Furthermore,with increasing the cycles of both processes,the planar isotropy decreases progressively.

ECAP与ARB纯铝的微观组织和力学性能的比较

采用ECAP和ARB2种剧烈塑性变形方法对L2纯铝进行加工,对比分析了材料的微观组织和力学性能变化。结果表明,ECAP和ARB都能细化晶粒、增加硬度、提高抗拉强度。但由于ECAP和ARB细化晶粒的机理不同,所以经过相同变形量后纯铝的晶粒细化程度不同,显微硬度和抗拉强度的增幅也不同。ECAP10道次后等轴晶均匀,晶粒大小约为1μm;ARB轧制7道次后超细晶增多,晶粒最小可以细化到500nm左右。

累积叠轧焊Al/Mg/Al多层复合材料的腐蚀行为

研究累积叠轧焊(ARB)Al1050/AZ31/Al1050多层复合材料的腐蚀行为,腐蚀介质为3.5%Na Cl(质量分数)溶液,分析测试手段包括动电位极化测试(PDP)、电化学阻抗谱(EIS)、扫描电子显微镜(SEM-EDS)、拉曼光谱和X射线衍射(XRD)等。为了深入研究Al1050/AZ31/Al1050多层复合材料的耐腐蚀性和腐蚀产物,对ARB制备的Al1050/Al1050/Al1050多层复合材料进行了相似的测试作为对比。动电位极化曲线和电化学阻抗谱显示,ARB应变水平会显著影响腐蚀速率。与Al1050/Al1050/Al1050样品相比,Al1050/AZ31/Al1050多层复合材料具有更高的腐蚀速率和更低的极化电阻。AZ31层对腐蚀过程起主导作用。拉曼和XRD分析结果表明主要腐蚀产物为Mg(OH)2,且不含任何氯化合物(如(Mg(OH)_(2))·MgCl_(2))。

累积叠轧道次对AZ31镁合金板微观组织和力学性能的影响

开展400℃轧制温度下的累积叠轧试验,并利用光学显微镜、拉伸试验机、显微硬度计、X射线衍射仪、扫描电镜对不同累积叠轧道次板材的微观组织和力学性能进行表征,研究累积叠轧道次对AZ31镁合金板材晶粒尺寸、基面织构、力学性能的影响。结果表明:累积叠轧工艺的晶粒细化主要发生在前3道次,随后的循环道次中晶粒不再明显细化,甚至略微长大。第3道次的综合力学性能最佳。剪切带的存在虽缓解了应力集中,提高了塑性,弱化了基面织构,但该处也易形成裂纹,加速板材的断裂,使伸长率急剧下降。基面织构强度随着轧制道次的增加呈先减弱后增强的趋势。

Development of through-thickness texture gradient and persistence of shear-type textures during annealing of commercial purity aluminium sheet processed by accumulative roll-bonding

Ultrafine-grained commercial-purity aluminum（AA1070） sheets produced by four cycles of accumulative roll-bonding（ARB） without lubrication are subjected to annealing treatments in the temperature range from 250℃ to 400℃.Microstructures and microtextures in the surface and center regions of the ARBed and annealed sheets are measured by electron backscatter diffraction.The results show that annealing treatments at 325℃ or above lead to a reduction in the microstructure gradient but a significant through-thickness texture gradient different from that in the as-deformed state.The center region is featured by the development of a strong cube texture at the expense of rolling components.In the surface region,shear-type components are either enhanced or largely retained,showing a high persistency upon annealing.While the grain structures are restored predominantly by continuous recrystallization in the surface region,a mixture of continuous and discontinuous recrystallization is envisaged for the center region.

Microstructural Evolution and Mechanical Properties of Laminated CuAl Composites Processed by Accumulative Roll-Bonding and Annealing

Nano structured Cu-/Al-laminated composites were processed by accumulative roll-bonding(ARB)technique for four cycles.Microstructural evolutions inside the Cu and Al layers and the interfacial reactions were revealed after annealing at different temperatures.Recovery and recrystallization occurred in the Cu and Al layers at low annealing temperatures,and three kinds of intermetallic compounds formed near the interfaces.The mechanical properties of these composites after annealing were investigated by tensile tests,and the variation of strength-ductility synergy was comprehensively discussed by considering the roles of constituent and the intermetallic compounds.

Processing of AZ31 magnesium alloy by accumulative roll-bonding at gradient temperature

In the present investigation a wrought magnesium alloy AZ31 was successfully processed by the accumulative roll-bonding （ARB） at gradient temperature up to six cycles with the lowest temperature of 250 °C. This is performed through different thermomechanical processing routes （different ARB cycles at different temperatures of 350-200 °C）. The microstructures and mechanical properties were investigated. The results indicate that significant grain refinement is observed after the first two cycles at the highest ARB temperature as a result of dynamic recrystallization, which is necessary for the subsequently ARB cycles at relatively lower temperature with the aim to restrict grain growth. No significant finer grain size was observed through the fifth and sixth cycles while the microstructure homogeneity is further improved. The grain structure can be effectively refined at lower ARB processing temperature and higher cycles. The resulting material exhibited high strength and relatively high ductility at ambient temperature when ARB deformed above 250 °C. The mechanical properties of the ARB deformed materials are strongly dependent on several main factors： the amount and the homogeneity of strain achieved, grain size and microstructure homogeneity, textures developed during ARB and interface bonding quality.

热处理对ARB1060纯铝组织与性能的影响

在室温条件下对1060工业纯铝进行7道次的累积叠轧焊轧制,将综合力学性能较好的ARB道次试样进行热处理实验研究,分析经过ARB剧烈塑性变形的金属材料在热处理条件下其微观组织与力学性能的变化。实验结果表明,ARB 5道次材料的综合力学性能较好,其抗拉强度为210 MPa,延伸率为9.3%。ARB 5道次试样在200℃以下温度条件下进行热处理,其拉伸性能稳定,显微组织处于回复阶段,超细晶材料组织和性能具有良好的稳定性。

累积复合轧制对镁合金组织和力学性能的影响

采用累积复合轧制技术对MB2镁合金进行轧制。采用光学显微镜、透射电镜和电子拉伸机等设备分析变形前及不同道次后MB2镁合金的微观组织和力学性能。结果表明:MB2镁合金经ARB轧制后,材料平均晶粒尺寸由变形前17.8μm有效细化到1.2μm;材料的抗拉强度和显微硬度值分别提高到300MPa和82.1;伸长率在ARB1道次后从24%下降到11.2%,且随着ARB轧制道次的增加,材料组织的均匀程度提高,抗拉强度和硬度值变化平缓,伸长率回升至22.5%。

纯铜深度塑性变形的织构组织均匀性研究

为了获得均匀的深度塑性变形纯铜织构组织,分别采用异步叠轧法和同步叠轧法制备纯铜试样.用X射线衍射极图法测量织构沿样品板厚方向的分布.结果表明,异步叠轧试样近表层的变形织构是{100}<011>剪切织构,同步叠轧试样的变形织构是{211}<111>铜织构,异步叠轧和同步叠轧试样里面各层的变形织构都是铜织构,并且强度非常接近,变形织构沿中心层呈对称分布;当真应变大于4.2时,增加应变对变形织构的组分和强度几乎没有影响;在叠轧中相邻2层的界面限制了晶粒的变形范围,使变形织构组织更均匀.

累积叠轧焊温度和循环道次对AZ31镁合金组织和性能的影响

研究了累积叠轧焊温度变化和循环道次对AZ31镁合金板材组织和性能的影响,分析了累积叠轧焊工艺细化AZ31镁合金晶粒的机理。试验结果表明,加热温度从250℃增加到400℃时,第一个道次后的平均晶粒尺寸逐渐减小;在400℃保温5min、道次压下量为50%时,第二个道次的板材平均晶粒尺寸可以细化到1.3μm,抗拉强度为300MPa,伸长率达到25.2%。

累积叠轧焊制备Al／AZ31多层复合材料及其强度

采用累积叠轧焊法制备了Al/AZ31多层复合材料,并通过扫描电镜、X射线能谱仪和显微硬度计对所制备的Al/AZ31多层复合材料进行了横截面形貌观察、能谱分析以及显微硬度测试。结果表明,经过三道次的累积叠轧焊之后可制备Al/AZ31多层复合材料。能谱分析表明,在Al层和AZ31层的界面处产生了扩散层,随着轧制道次的增加扩散层的厚度逐渐增加。显微硬度测试表明,随着轧制道次的增加,Al/AZ31多层复合材料的层组元的强度也随之增加,但Al层的强度较AZ31增加得快,并且形成的界面扩散层具有一定的硬度梯度。

以TiH_2为发泡剂制备泡沫铝的研究现状

探讨了发泡剂发泡法、粉末冶金发泡法、累积叠轧焊法中以TiH2为发泡剂制备泡沫铝的研究进展。在发泡剂发泡法中,对TiH2发泡剂高温下分解过快问题采取了热处理、化学改性、包覆等方法以减缓其释气速率,使泡沫铝生产易于控制;在粉末冶金发泡法、累积叠轧焊法制备泡沫铝夹心板的过程中,后者更有利于TiH2发泡剂的均匀分布。

累积叠轧1060工业纯铝的微观组织和性能

采用累积叠轧方法对1060工业纯铝进行变形,分析了变形前后其微观组织和力学性能。试验结果表明,累积叠轧4道次后工业纯铝的抗拉强度提高了60 N/mm2,硬度提高了一倍。在第一道次之后伸长率下降较大,从45%下降到12%,但在以后道次中保持稳定。随着变形道次的增加,纤维组织越来越细。当累计变形量大于75%时其复合界面焊合较好,断裂裂纹很容易在复合界面形核,并沿着复合界面扩展延伸。

累积叠轧焊对L2纯铝力学性能影响的研究

通过实验研究了轧制道次、温度与材料状态对L2纯铝力学性能的影响。结果表明:材料的抗拉强度、屈服强度和显微维氏硬度随轧制道次的增加而增加,第10道次分别为190.44MPa、152.27MPa和49.3HV(载荷100g);室温叠轧材料的强度要高于热叠轧的,而延伸率却低于热叠轧的;半硬化态L2纯铝和完全退火态L2纯铝的强化能力是一致的,但半硬化态L2纯铝的强化幅度要低于完全退火态的。

塑性变形及热处理对2024铝合金组织与性能的影响

利用扫描电子显微镜、拉伸试验机和布氏硬度计研究了累积复合轧制(ARB)道次和热处理对2024铝合金组织和力学性能的影响。结果表明:随着ARB道次的增加,2024铝合金组织均匀细小,强度、硬度增加,经过两道次轧制后分别达到236.4 MPa和68.5 HB,伸长率下降,由原来的31.7%降低到16.1%;随着时效温度的增加,经ARB 2道次轧制的2024合金的硬度降低,由68.5 HB降低到51.8HB。

累积叠轧焊制备超细晶IF钢微观组织与力学性能

采用累积叠轧焊方法制备了超细晶IF钢 ,对其微观组织和力学性能进行了分析。实验结果表明 ,累积叠轧后IF钢的平均晶粒尺寸为 70 0nm ;抗拉强度为 62 1 3MPa ,达到冷轧IF钢抗拉强度的 2 0 2倍 ,屈强比σ0 2 /σb 为 0 81。

两种塑性变形加工1060纯铝的组织和性能研究

采用等通道角挤压变形和累积叠轧焊两种大塑性变形方法对1060纯铝进行了加工,研究分析了纯铝在加工后的微观组织和力学性能变化和规律。结果表明:在相同的累积变形条件下,ARB和ECAP都能实现材料的晶粒细化和力学性能改善的目的。但由于两种塑性加工方式细化晶粒的机理和加工工艺不同,所以晶粒细化程度和力学性能的改善程度有所差别。ARB法将晶粒最小可以细化到500nm左右,ECAP法能细化晶粒到大小约为1μm。

1060工业纯铝累积叠轧后的力学性能

采用累积叠轧焊方法在室温下加工1060工业纯铝,分析了叠轧变形前后其力学性能的变化。结果表明:随着累积叠轧道次的增加,材料的抗拉强度和显微硬度都得到提高;拉伸断口处的韧窝逐渐变小变浅,但仍为韧性断裂;轧制1道次后试样的伸长率较母材的伸长率急剧降低,随着轧制的进行伸长率变化平稳;累积叠轧5道次材料的综合力学性能较好,抗拉强度提高到210 MPa,是母材的2.41倍,显微硬度78.5 HV,是母材的2.2倍,伸长率9.3%,仅是母材的0.21倍。

泡沫铝累积叠轧制备方法及孔隙结构研究

以L2纯铝为基体金属,TiH2粉末为发泡剂,通过累积叠轧试验,探索泡沫铝制备的新方法。结果显示,叠轧道次对泡沫铝孔隙率与平均孔径影响显著,叠轧道次越多,孔隙率越高,平均孔径越小;TiH2含量与发泡温度是影响发泡驱动力的主要因素,试验温度范围内,发泡剂含量越大,温度越高,发泡驱动力越强,发泡后孔隙率越高,并且平均孔径也越大。叠轧6道次的L2纯铝,发泡剂含量0.5%(质量分数),在670℃条件下发泡5min,可以获得孔隙率61.4%,平均孔径1.6mm的泡沫铝。上述研究表明,累积叠轧焊是一种有效的泡沫铝制备方法,通过工艺参数的优化,可以获得孔隙均匀,高孔隙率的泡沫铝。