CN110465662A - 一种原位调控镍钛合金功能特性的4d打印方法及应用 - Google Patents
一种原位调控镍钛合金功能特性的4d打印方法及应用 Download PDFInfo
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Abstract
本发明属于增材制造技术领域,公开了一种原位调控镍钛合金功能特性的4D打印方法及应用。将镍钛合金棒材通过雾化制粉,获得粒径为15~53μm的镍钛合金粉末,然后置于放电等离子体辅助球磨机中进行放电处理,促进粉末活性激活,然后加入粒径为100~800nm的纳米级镍粉,得到混合粉末,继续进行放电处理,使镍钛合金粉末与纳米镍粉之间实现冶金结合,得到改性粉末,最后将改性粉末通过增材制造技术制备成形,得到功能化的镍钛合金。本发明通过在放电处理过程中加入纳米级镍粉与大尺寸球形镍钛合金粉末实现冶金结合,有利于制备出成分、组织、性能均匀的块体合金及其零件。
Description
技术领域
本发明属于增材制造技术领域,具体涉及一种原位调控镍钛合金功能特性的4D打印方法及应用。
背景技术
镍钛基形状记忆合金具有优异的生物相容性,广泛应用于牙列矫正丝、脊柱矫形棒、血管成形环和手术用微型钳子等生物医疗领域。同时,利用其优良的形状记忆效应和超弹性,广泛应用于管路接头、管路固定、弹簧驱动装置、温度控制器、温度传感器触发器等领域;利用其高阻尼性能,广泛应用于振动控制构件、锥形阻尼器等领域;利用其优良的耐腐蚀性能,在化工、船舶零件等领域也存在广泛的应用前景。
然而,对于镍钛形状记忆合金而言,其相变温度对化学成分很敏感,在熔炼、铸造、轧制等过程中会引入杂质元素(如C、N等),改变其相转变温度,进而影响其功能特性(参考文献1:Acta Mater.58(2010)3444-3458.)。此外,镍钛形状记忆合金热导率较低、加工性能差,降低了其加工生产效率,因而对于精密复杂镍钛合金零件,譬如多孔结构、薄壁结构等,采用传统工艺无法成形或成形及其困难(参考文献2:Prog.Mater.Sci.57(2012)911-946.)。在4D打印制备镍钛合金过程中,由于激光与粉末作用使得熔池温度很高,镍原子会存在挥发现象,这会导致成型件的镍钛原子比发生变化,进而相转变温度发生较大变化,无法满足特定的服役要求(参考文献3:Scr.Mater.146(2018)164-168.)。因此,探索新的镍钛合金成形工艺,且有效调控其相转变温度,成为急需解决的问题。目前,4D打印镍钛合金的相转变温度一般采用热处理方式进行调控,关于原位调控4D打印镍钛合金相转变温度及其功能特性,同时制备出高致密度的镍钛合金及其零部件的案例鲜有报道(参考文献4:Prog.Mater.Sci.83(2016)630-663.)。
4D打印是对智能材料的增材制造(3D打印)制备技术,4D打印技术能够实现结构功能一体化设计。作为一种重要的智能材料,镍钛合金4D打印技术已经得到了研究者的广泛关注,其能按照三维数据模型直接将金属粉末在外加热源作用下完全熔化,并凝固成形为具有良好冶金结合和高精度的金属零件,特别适合薄壁、内腔复杂、内流道等传统加工技术难以实现的复杂薄壁精密构件的制造。在4D打印成形过程中存在高纯氩气保护,氧含量低于300ppm,可以极大地减少成形件的杂质含量。目前,增材制造的粉末制备技术主要包括气雾化法和水雾化法,针对镍钛合金粉末,目前主要采用旋转电极气雾化法制备,一次只能制备出单一组分的镍钛合金粉末,调控成分困难、成本高,商业化应用的镍钛合金成分单一。
发明内容
针对以上现有技术存在的缺点和不足之处,本发明的首要目的在于提供一种原位调控镍钛合金功能特性的4D打印方法。该方法提出采用4D打印技术实现对镍钛合金粉末+纳米级镍粉的混合粉末的增材制造成形,通过调控镍钛合金粉末和纳米镍粉的混合比例,进而精确调控4D打印镍钛合金的镍钛原子比,最终调控其相转变温度和功能特性,以拓展镍钛合金的产业化应用领域。
本发明的另一目的在于提供一种通过上述方法得到的镍钛合金。
本发明的再一目的在于提供上述镍钛合金在制备脊柱矫形棒、髓内针/钉、血管成形环或手术用微型钳子等生物医疗器械;管路接头、智能控温器件、弹簧驱动装置、温度传感器触发器等化工、卫浴装置;振动控制构件、锥形阻尼器;自展开桁架、自展开通讯卫星零部件等航空航天领域部件中的应用。
本发明目的通过以下技术方案实现:
一种原位调控镍钛合金功能特性的4D打印方法,包括如下步骤:
(1)制粉:将纯钛和纯镍进行配料、熔炼,得到镍钛合金棒材,然后通过旋转电极雾化法制取合金粉末,对粉末进行筛分处理,获得粒径为15~53μm的镍钛合金粉末;
(2)粉末改性:将步骤(1)所得镍钛合金粉末置于放电等离子体辅助球磨机中进行放电处理,促进粉末活性激活,然后加入粒径为100~800nm的纳米级镍粉,得到混合粉末,继续进行放电处理,使镍钛合金粉末与纳米镍粉之间实现冶金结合,得到改性粉末;
(3)4D打印成形:将步骤(2)处理后的改性粉末通过增材制造技术制备成形,得到功能化的镍钛合金。
优选地,步骤(1)中所述镍钛合金粉末的原子百分比元素组成为:Ti50~60at.%,余量为Ni。
优选地,步骤(2)中所述纳米级镍粉的加入量使得混合粉末的原子百分比元素组成为:Ti 45~50at.%,余量为Ni。
优选地,步骤(2)中促进粉末活性激活的放电处理条件为:电压120~130V,电流1~1.4A,电极转速800~1000r/min,每次放电处理持续时间为0.5~1.5h,相邻两次放电处理的间隔为30~60min,放电处理次数为3~6次;加入纳米级镍粉后,继续进行放电处理降低电极转速到500~700r/min,调整电流到1.5~1.8A,继续处理2~4h。
优选地,步骤(3)中所述增材制造技术是指选区激光熔化(SLM)成形技术,具体参数条件为:激光功率P>60W,激光扫描速度v>100mm/s,激光扫描间距h=80~120μm,铺粉层厚t=25~40μm。
一种镍钛合金,通过上述方法制备得到。
上述镍钛合金在制备脊柱矫形棒、髓内针/钉、血管成形环或手术用微型钳子等生物医疗器械;管路接头、智能控温器件、弹簧驱动装置、温度传感器触发器等化工、卫浴装置;振动控制构件、锥形阻尼器;自展开桁架、自展开通讯卫星零部件等航空航天领域部件中的应用。
本发明的原理为:本发明通过在放电处理过程中加入纳米级镍粉,采用放电等离子球磨使纳米镍粉均匀涂敷于大尺寸球形镍钛合金粉末表面,实现冶金结合,一方面有利于使粉末维持较好的球形形态,另一方面能够直接有效地控制4D打印镍钛合金基体的镍含量,进而调控其相转变温度,进而有利于制备出成分、组织、性能均匀的块体合金及其零件。
相对于现有技术,本发明具有如下优点及有益效果:
(1)由于镍钛形状记忆合金的相转变温度对其镍含量十分敏感,采用原位添加一定量镍粉的混合粉末作为原材料,能够直接有效地控制4D打印镍钛合金基体的镍含量,进而调控其相转变温度,同时基于混合粉末制备的镍钛合金的致密度超过99%,硬度大于300HV,由单一B2奥氏体相组成,超弹性能应变达到5.2%。
(2)相对单纯混粉或混粉球磨来说,本发明采用放电等离子球磨使纳米镍粉均匀涂敷于大尺寸球形镍钛合金粉末表面,实现冶金结合,进而有利于制备出成分、组织、性能均匀的块体合金及其零件。
(3)本发明采用4D打印成形工艺制备镍钛形状记忆合金,根据设计的三维模型可以完成复杂形状镍钛合金零件的成形,实现复杂结构镍钛合金零件的快速制造,可以大大拓展镍钛合金在医疗、卫浴、航空航天等领域的应用。
附图说明
图1为实施例1中改性混合粉末的粒径分布图。
具体实施方式
下面结合实施例及附图对本发明作进一步详细的描述,但本发明的实施方式不限于此。
实施例1
1.雾化制粉。按照下述镍钛原子比进行配料:Ti 50.6at.%,Ni 49.4at.%。在真空条件下熔炼出镍钛合金棒材。棒材雾化,收集所得到的原始粉末,进行筛选处理,控制目标粉末的粒径在15~53μm范围内。
2.粉末改性。运用Plasma-BM-S型等离子体球磨机对筛选出的镍钛合金粉末(质量m1)进行放电处理。控制参数为:电压130V,电流1.4A,电极转速800r/min,每次放电处理持续时间为0.5h,相邻两次放电处理的间隔为30min,放电等离子体处理次数为6次。随后,添加粒径为100nm的镍粉至放电等离子体处理的镍钛合金粉末,添加质量m2,控制m1:m2=30:1,使得混合粉末中Ti:Ni=49.1:50.9(at.%),调整电极转速至600r/min,电流控制在1.8A,对混合粉末继续放电处理2h,得到最终的改性混合粉末。
所得改性混合粉末的粒径分布图如图1所示。所得改性混合粉末与未改性的原始粉末的粒径对比如表1所示。
表1
由图1及表1结果可见:纳米镍粉添加、等离子体处理对粉末形貌影响小,纳米镍粉在镍钛合金粉末表面涂覆均匀,混合粉末粒径分布均匀。
3.4D打印成形。运用增材制造成形设备对放电等离子体处理的改性混合粉末和未改性的原始粉末分别进行4D打印成形,工艺参数为:激光功率P=70W,激光扫描速度ν=105mm/s,激光扫描间距h=100μm,铺粉层厚t=30μm。
4.改性效果评估。将以上步骤4D打印成形的试样表面磨光,通过阿基米德排水法测其致密度,采用DHV-1000Z设备、X射线衍射仪和差示扫描量热法测试其硬度、相组成和相转变温度,通过Instron 8862设备测试其超弹性。结果表明,本实施例中改性混合粉末4D打印成形的镍钛合金致密度为99.5%,硬度为327±8HV,由单一B2奥氏体相组成,马氏体转峰值温度与奥氏体转变峰值温度分别为:-12.7℃和9.4℃。此外,在压缩条件下,改性混合粉末4D打印成形件在室温下(奥氏体状态)其超弹性应变达到5.29%,应变回复率超过93.6%。未改性混合粉末4D打印成形的镍钛合金致密度为98.1%,硬度为281±9HV,由单一B2奥氏体相组成,马氏体转峰值温度与奥氏体转变峰值温度分别为:-17.1℃和8.3℃,在压缩条件下,未改性混合粉末4D打印成形件在室温下(奥氏体状态)其超弹性应变达到4.03%,应变回复率超过85.1%。
实施例2
1.制粉。按照下述镍钛原子比进行配料:Ti 60at.%,Ni 40at.%。在真空条件下熔炼出镍钛合金棒材。棒材雾化,收集所得到的原始粉末,进行筛选处理,控制目标粉末的粒径在15~53μm范围内。
2.粉末改性。运用Plasma-BM-S型等离子体球磨机对筛选出的镍钛合金粉末(质量m1)进行放电处理。控制参数为:电压120V,电流控制在1A,电极转速1000r/min,每次放电处理持续时间为1h,相邻两次放电处理的间隔为45min,放电处理次数为3次。原始粉末处理结束后添加粒径为500nm的镍粉,添加质量m2,控制m1:m2=4.91:1,使得混合粉末中钛镍原子比为Ti 49.2Ni 50.8(at.%),调整电极转速至700r/min,电流控制在1.8A,接着对混合粉末继续进行放电处理4h,得到最终改性混合粉末。分析结果表明球形粉末形貌变化小,纳米镍粉在镍钛合金粉末表面涂覆均匀,混合粉末粒径分布均匀。
3.4D打印成形。运用增材制造成形设备对改性混合粉末和未改性的原始粉末分别进行4D打印成形,工艺参数为:激光功率P=250W,激光扫描速度ν=1250mm/s,激光扫描间距h=100μm,铺粉层厚t=35μm。
4.改性以及成形效果评估。将以上步骤4D打印成形的试样表面磨光,通过阿基米德排水法测其致密度,采用DHV-1000Z设备、X射线衍射仪和差示扫描量热法测试其硬度、相组成和相转变温度,通过Instron 8862设备测试其超弹性。结果表明,本实施例中改性混合粉末通过4D打印技术制备得到的镍钛合金的致密度为99.1%,硬度为319±9HV,混合粉体4D打印成形件由单一B2奥氏体相组成,马氏体转峰值温度与奥氏体转变峰值温度分别为:-2.4℃和17.1℃,此外,在压缩条件下,混合粉体4D打印成形件在室温下(奥氏体状态)其超弹性应变达到5.21%,应变回复率超过94.2%。未改性混合粉末4D打印成形的镍钛合金致密度为98.3%,硬度为279±7HV,由单一B2奥氏体相组成,马氏体转峰值温度与奥氏体转变峰值温度分别为:-4.3℃和10.3℃,在压缩条件下,未改性混合粉末4D打印成形件在室温下(奥氏体状态)其超弹性应变达到4.26%,应变回复率超过74.2%。
实施例3
1.制粉。按照下述镍钛原子比进行配料:Ti 50at.%,Ni 50at.%。在真空条件下熔炼出镍钛合金棒材。棒材雾化,收集所得到的原始粉末,进行筛选处理,控制目标粉末的粒径在15~53μm范围内。
2.粉末改性。运用Plasma-BM-S型等离子体球磨机对筛选出的镍钛合金粉末(质量m1)进行放电处理。控制参数为:电压125V,电流控制在1.4A,电极转速800r/min,每次放电处理持续时间为1.5h,相邻两次放电处理的间隔为30min,放电处理次数为3次。原始粉末处理结束后添加粒径为300nm的镍粉,添加质量m2,控制m1:m2=44.4:1,使得混合粉末中钛镍原子比为Ti 49Ni 51(at.%),调整电极转速至500r/min,电流控制在1.8A,接着对混合粉末继续进行放电处理3h,得到最终改性混合粉末。分析结果表明球形粉末形貌变化小,纳米镍粉在镍钛合金粉末表面涂覆均匀,混合粉末粒径分布均匀。
3.4D打印成形。运用增材制造成形设备对改性混合粉末和未改性的原始粉末分别进行4D打印成形,工艺参数为:激光功率P=200W,激光扫描速度ν=1000mm/s,激光扫描间距h=80μm,铺粉层厚t=40μm。
4.改性以及成形效果评估。将以上步骤4D打印成形的试样表面磨光,通过阿基米德排水法测其致密度,采用DHV-1000Z设备、X射线衍射仪和差示扫描量热法测试其硬度、相组成和相转变温度,通过Instron 8862设备测试其超弹性。结果表明,本实施例中改性混合粉末通过4D打印技术制备得到的镍钛合金的致密度为99.2%,硬度为304±9HV,混合粉体4D打印成形件由单一B2奥氏体相组成,马氏体转峰值温度与奥氏体转变峰值温度分别为:-12.1℃和7.9℃,此外,在压缩条件下,混合粉体4D打印成形件在室温下(奥氏体状态)其超弹性应变达到5.17%,应变回复率超过91.2%。未改性混合粉末4D打印成形的镍钛合金致密度为97.1%,硬度为271±6HV,由单一B2奥氏体相组成,马氏体转峰值温度与奥氏体转变峰值温度分别为:-14.7℃和6.1℃,在压缩条件下,未改性混合粉末4D打印成形件在室温下(奥氏体状态)其超弹性应变达到3.91%,应变回复率超过69.2%。
上述实施例为本发明较佳的实施方式,但本发明的实施方式并不受上述实施例的限制,其它的任何未背离本发明的精神实质与原理下所作的改变、修饰、替代、组合、简化,均应为等效的置换方式,都包含在本发明的保护范围之内。
Claims (7)
1.一种原位调控镍钛合金功能特性的4D打印方法,其特征在于包括如下步骤:
(1)制粉:将纯钛和纯镍进行配料、熔炼,得到镍钛合金棒材,然后通过旋转电极雾化法制取合金粉末,对粉末进行筛分处理,获得粒径为15~53μm的镍钛合金粉末;
(2)粉末改性:将步骤(1)所得镍钛合金粉末置于放电等离子体辅助球磨机中进行放电处理,促进粉末活性激活,然后加入粒径为100~800nm的纳米级镍粉,得到混合粉末,继续进行放电处理,使镍钛合金粉末与纳米镍粉之间实现冶金结合,得到改性粉末;
(3)4D打印成形:将步骤(2)处理后的改性粉末通过增材制造技术制备成形,得到功能化的镍钛合金。
2.根据权利要求1所述的一种原位调控镍钛合金功能特性的4D打印方法,其特征在于:步骤(1)中所述镍钛合金粉末的原子百分比元素组成为:Ti50~60at.%,余量为Ni。
3.根据权利要求1所述的一种原位调控镍钛合金功能特性的4D打印方法,其特征在于:步骤(2)中所述纳米级镍粉的加入量使得混合粉末的原子百分比元素组成为:Ti 45~50at.%,余量为Ni。
4.根据权利要求1所述的一种原位调控镍钛合金功能特性的4D打印方法,其特征在于步骤(2)中促进粉末活性激活的放电处理条件为:电压120~130 V,电流1~1.4 A,电极转速800~1000r/min,每次放电处理持续时间为0.5~1.5h,相邻两次放电处理的间隔为30~60min,放电处理次数为3~6次;加入纳米级镍粉后,继续进行放电处理降低电极转速到500~700r/min,调整电流到1.5~1.8 A,继续处理2~4h。
5.根据权利要求1所述的一种原位调控镍钛合金功能特性的4D打印方法,其特征在于:步骤(3)中所述增材制造技术是指SLM成形技术,具体参数条件为:激光功率P>60 W,激光扫描速度v>100mm/s,激光扫描间距h=80~120μm,铺粉层厚t=25~40μm。
6.一种镍钛合金,其特征在于:通过权利要求1~5任一项所述的方法制备得到。
7.权利要求6所述的镍钛合金在制备脊柱矫形棒、髓内针/钉、血管成形环、手术用微型钳子、管路接头、智能控温器件、弹簧驱动装置、温度传感器触发器、振动控制构件、锥形阻尼器、自展开桁架、自展开通讯卫星零部件中的应用。
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