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  4. 1050铝基PS版的热处理工艺

材料科学与工程学报, 2008, 26(3): 416-421.

1050铝基PS版的热处理工艺

李红英 1, , 王法云 2, , 曾再得 3, , 约束SiC陶瓷的轻型复合结构为研究对象,研究陶瓷背部、面部、侧面的约束厚度对复合结构抗12.7 mm穿甲弹性能的影响。结果表明:对SiC陶瓷施加约束可提升陶瓷的防护性能;各约束厚度均存在一合理值。进行约束厚度优化,得到陶瓷组元抗弹潜能较充分发挥,且结构整体抗弹性能良好的轻型复合结构。","authors":[{"authorName":"李树涛","id":"0667a82c-95e5-4a53-9edf-a718e359ca9c","originalAuthorName":"李树涛"},{"authorName":"钟涛","id":"e2ca1c83-c898-4a9d-a078-68a001677934","originalAuthorName":"钟涛"},{"authorName":"苗成","id":"35432c8b-8aba-436f-a7ce-4a31b5b36cc3","originalAuthorName":"苗成"},{"authorName":"杨伟苓","id":"d2241acc-22b6-4e36-b683-6ecfec0a6e60","originalAuthorName":"杨伟苓"},{"authorName":"白利红","id":"8f26dfd1-7993-4d74-bd96-2ca275480790","originalAuthorName":"白利红"}],"doi":"","fpage":"1","id":"698ff0aa-8d59-4dd9-a1db-d3eeb5ae340b","issue":"1","journal":{"abbrevTitle":"BQCLKXYGC","coverImgSrc":"journal/img/cover/BQCLKXYGC.jpg","id":"4","issnPpub":"1004-244X","publisherId":"BQCLKXYGC","title":"兵器材料科学与工程 "},"keywords":[{"id":"9586b12f-7c17-4785-8ddb-0878aa6f8d47","keyword":"防护","originalKeyword":"防护"},{"id":"38fdc9a5-d04c-436a-b187-210619c97695","keyword":"约束效应","originalKeyword":"约束效应"},{"id":"c5414b2b-b6ba-4adf-8c70-99b9d120b719","keyword":"数值优化","originalKeyword":"数值优化"},{"id":"3c7c6127-03cf-4c4e-ab15-5a8e5802a00d","keyword":"陶瓷复合结构","originalKeyword":"陶瓷复合结构"},{"id":"c26bea40-f972-4aa6-a75a-3e91be130ccd","keyword":"抗弹性能","originalKeyword":"抗弹性能"},{"id":"021215cc-6a73-40ab-b7f5-cd07c456af43","keyword":"约束厚度","originalKeyword":"约束层厚度"}],"language":"zh","publisherId":"bqclkxygc201401001","title":"Al/SiC陶瓷复合结构中Al约束厚度的数值优化","volume":"","year":"2014"},{"abstractinfo":"将梁结构剪切中性轴的概念推广至约束阻尼板结构中,提出了剪切中性面的概念.基于变形能原理,对板类约束阻尼结构的结构损耗因子进行厚度参数优化理论分析,并进行试验验证.结果表明,阻尼较薄时,阻尼厚度约束厚度的优化理论分析结果与试验数据变化趋势一致,表明了理论分析方法的合理性.","authors":[{"authorName":"黄加才","id":"fbfc2794-aedf-40f8-accd-713bc79a0877","originalAuthorName":"黄加才"},{"authorName":"游少雄","id":"73d5827e-9af7-42a2-85f5-d9485daf7601","originalAuthorName":"游少雄"},{"authorName":"赵云峰","id":"4eeada66-431c-4079-a0f4-35c44cdda67a","originalAuthorName":"赵云峰"}],"doi":"","fpage":"30","id":"5c33c58e-5b8a-45e7-ba58-32e082e02325","issue":"1","journal":{"abbrevTitle":"YHCLGY","coverImgSrc":"journal/img/cover/YHCLGY.jpg","id":"77","issnPpub":"1007-2330","publisherId":"YHCLGY","title":"宇航材料工艺 "},"keywords":[{"id":"f1b0b887-c8c1-471f-a356-592397e2ca8b","keyword":"约束阻尼结构","originalKeyword":"约束阻尼结构"},{"id":"07aa92cf-7053-40f2-81d4-bf11dea2b11c","keyword":"阻尼板","originalKeyword":"阻尼板"},{"id":"6bccae24-b403-4b1c-8621-070e4cacfb58","keyword":"结构损耗因子","originalKeyword":"结构损耗因子"},{"id":"54114def-dd42-446c-8015-7c5297180ae0","keyword":"优化","originalKeyword":"优化"}],"language":"zh","publisherId":"yhclgy201301006","title":"板类约束阻尼结构的厚度参数优化","volume":"43","year":"2013"},{"abstractinfo":"在文献[1]中,雷达罩变厚度蜂窝展开加工后被铺贴到模具上.本文针对蜂窝中的应力应变,运用几何学及力学的综合方法进行力学推导,得到蜂窝的应力应变数据,并确定雷达罩蜂窝展开加工的力学约束条件,从而对不同的雷达罩蜂窝材料加工的合理尺寸给出合理的判据.这种方法避免了传统的有限元方法中的复杂的有限元建模过程,也避免了有限元计算中的误差.在针对FEMAP程序二次开发后,本文的计算结果在FEMAP(参考文献[2])有限元软件中得到形象的显示,使二次开发的程序与有限元模型之间相互联通.","authors":[{"authorName":"李兴德","id":"5ca3d51a-b656-4a3a-ae30-35ae882ad713","originalAuthorName":"李兴德"},{"authorName":"周春苹","id":"888a8e0b-894c-404a-9730-9184124045e2","originalAuthorName":"周春苹"},{"authorName":"裘进浩","id":"b480ab4d-25c1-4cf8-a2e9-24401dc23c8a","originalAuthorName":"裘进浩"}],"doi":"","fpage":"70","id":"793733b7-4eec-4032-a135-c3b83b742a4e","issue":"6","journal":{"abbrevTitle":"BLGFHCL","coverImgSrc":"journal/img/cover/BLGFHCL.jpg","id":"6","issnPpub":"1003-0999","publisherId":"BLGFHCL","title":"玻璃钢/复合材料"},"keywords":[{"id":"bed38f0c-1b8f-4cac-b466-c1bb0e9c75d4","keyword":"变厚度","originalKeyword":"变厚度"},{"id":"7a4f0686-cc33-441a-9fde-1e60f7fbcf3c","keyword":"蜂窝材料","originalKeyword":"蜂窝材料"},{"id":"afd2f8ac-e9cc-4490-9cb8-df7c22223057","keyword":"夹层结构雷达罩","originalKeyword":"夹层结构雷达罩"},{"id":"dff776d8-9ca7-40df-97a6-7aea5b359ce6","keyword":"展开蜂窝加工","originalKeyword":"展开蜂窝加工"},{"id":"9d45052c-6aa9-44d3-9a0f-65b0eb7f5100","keyword":"力学约束条件","originalKeyword":"力学约束条件"}],"language":"zh","publisherId":"blgfhcl201406015","title":"雷达罩变厚度蜂窝展开加工的力学约束","volume":"","year":"2014"},{"abstractinfo":"对强度错配约束条件下LY12/Al/LY12四点弯曲试样界面纯铝内裂纹前端进行了弹塑性大变形平面应变应力场数值分析. 结果表明:在小范围屈服条件下随着中间纯铝厚度的降低, 其峰值载荷呈线性增加;强界面的约束使得其塑性变形由类似单金属纺锤形转变为平行于界面的纵向发展, 该趋势随其厚度降低而越来越明显;裂尖三轴应力约束及最大拉应力水平随载荷增加或纯铝厚度降低而升高, 且均随归一化J 积分增加沿一特定的路径变化. 当界面对纯铝塑性变形约束明显增加时, 高的三轴约束将诱发微裂纹和孔洞的萌生, 同时伴随着中间纯铝的脆化甚至局部解理.","authors":[{"authorName":"韩礼红","id":"228eb413-d396-4e4e-bde6-24c9cc0e37fc","originalAuthorName":"韩礼红"},{"authorName":"李梁","id":"2fb44076-db6e-40b8-88e6-ef0585bb34de","originalAuthorName":"李梁"},{"authorName":"孙军","id":"142273de-46a6-467e-b57a-6230b08edb79","originalAuthorName":"孙军"}],"categoryName":"|","doi":"","fpage":"920","id":"5512f429-819e-4724-ae7f-d45b8dd1422f","issue":"9","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"5e846c01-d3d9-4735-9276-71b1384bdd2b","keyword":"界面约束","originalKeyword":"界面约束"},{"id":"1359b4e1-0654-4e47-b0af-5314fd2ca64f","keyword":"pure Al","originalKeyword":"pure Al"},{"id":"359f3f1b-c1d0-4970-a61b-32258d86c3d8","keyword":"stress triaxiality","originalKeyword":"stress triaxiality"}],"language":"zh","publisherId":"0412-1961_2004_9_7","title":"约束条件下界面纯铝裂尖应力场的数值分析","volume":"40","year":"2004"},{"abstractinfo":"对强度错配约束条件下LY12/Al/LY12四点弯曲试样界面纯铝内裂纹前端进行了弹塑性大变形平面应变应力场数值分析.结果表明:在小范围屈服条件下随着中间纯铝厚度的降低,其峰值载荷呈线性增加;强界面的约束使得其塑性变形由类似单金属纺锤形转变为平行于界面的纵向发展,该趋势随其厚度降低而越来越明显;裂尖三轴应力约束及最大拉应力水平随载荷增加或纯铝厚度降低而升高,且均随归-化J积分增加沿一特定的路径变化.当界面对纯铝塑性变形约束明显增加时,高的三轴约束将诱发微裂纹和孔洞的萌生,同时伴随着中间纯铝的脆化甚至局部解理.","authors":[{"authorName":"韩礼红","id":"c4dfccc1-c445-4ede-bf3f-c28d1d808545","originalAuthorName":"韩礼红"},{"authorName":"李梁","id":"11477dc2-c501-45f1-8e4a-36ed87dc0c1a","originalAuthorName":"李梁"},{"authorName":"孙军","id":"6c333764-ed0a-4976-8c29-15f54ac6146c","originalAuthorName":"孙军"}],"doi":"10.3321/j.issn:0412-1961.2004.09.005","fpage":"920","id":"0db8bf51-669f-4d47-933d-3621595966f6","issue":"9","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"653aeeed-a79d-4e67-a1d1-bb125269b7d3","keyword":"界面约束","originalKeyword":"界面约束"},{"id":"4e5cfe08-d9b1-472b-a0f4-2715b03cfffd","keyword":"纯铝","originalKeyword":"纯铝"},{"id":"620d7b60-9ff3-4c27-bb05-d5a9c9f7c858","keyword":"三轴应力","originalKeyword":"三轴应力"},{"id":"ff63a084-ef9d-42e5-8e98-119a8a4a9248","keyword":"数值分析","originalKeyword":"数值分析"}],"language":"zh","publisherId":"jsxb200409005","title":"约束条件下界面纯铝裂尖应力场的数值分析","volume":"40","year":"2004"},{"abstractinfo":"利用爆炸焊及电子束焊接方法制备了含不同厚度中间纯铝的LY12 / Al / LY12 四点弯曲试样,并在纯铝中预制了平行于界面的疲劳裂纹.加载后裂纹尖端侧剖形貌的金相观察和对应断口表面的微区成分的能谱分析均确认了裂纹在纯铝内的扩展.实验结果表明:在双界面强约束下,随着中间纯铝厚度的减小,所测定的预裂纹试样的载荷/ 位移曲线表现出明显的差异;以其临界J 积分表征的断裂韧性值显著降低,即纯铝发生了韧脆转变;试样断口表面出现局部准解理花样等脆化特征,其所占比例逐渐增加;对这种约束下纯铝韧脆转变的微观机理进行了初步的探讨.","authors":[{"authorName":"韩礼红","id":"ce84318b-0631-4d3f-a9b1-daf4692610e0","originalAuthorName":"韩礼红"},{"authorName":"李梁","id":"c84ffc31-5186-4b9a-826f-d112b1e41c34","originalAuthorName":"李梁"},{"authorName":"孙军","id":"6986e7fd-51be-4217-b537-c4b2b18922af","originalAuthorName":"孙军"}],"categoryName":"|","doi":"","fpage":"920","id":"02042c65-4abe-4984-b1c9-135fe0f25286","issue":"9","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"477837c5-2ae9-4eae-91a8-4abd15a073c5","keyword":"纯铝","originalKeyword":"纯铝层"},{"id":"cf7ecb75-5607-46b7-815a-0d6d9b40dc97","keyword":"null","originalKeyword":"null"},{"id":"faa83fc2-6af7-47dd-9406-cc38e1f6c03f","keyword":"null","originalKeyword":"null"}],"language":"zh","publisherId":"0412-1961_2003_9_19","title":"双界面约束下纯铝韧脆转变行为的实验研究","volume":"39","year":"2003"},{"abstractinfo":"利用爆炸焊及电子束焊接方法制备了含不同厚度中间纯铝的LYl2/Al/LY12四点弯曲试样,并在纯铝中预制了平行于界面的疲劳裂纹加载后裂纹尖端侧剖形貌的金相观察和对应断口表面的微区成分的能谱分析均确认了裂纹在纯铝内的扩展.实验结果表明:在双界面强约束下,随着中间纯铝厚度的减小,所测定的预裂纹试样的载荷/位移曲线表现出明显的差异;以其临界J积分表征的断裂韧性值显著降低,即纯铝发生了韧脆转变;试样断口表面出现局部准解理花样等脆化特征,其所占比例逐渐增加;对这种约束下纯铝韧脆转变的微观机理进行了初步的探讨.","authors":[{"authorName":"韩礼红","id":"a73b688c-e1ca-4cf6-af97-20c45af4d883","originalAuthorName":"韩礼红"},{"authorName":"李梁","id":"3d55c672-a818-4d6b-8b94-296ed10fcc81","originalAuthorName":"李梁"},{"authorName":"孙军","id":"f8d69a57-e7d2-45d4-ae5f-61819f3d742c","originalAuthorName":"孙军"}],"doi":"10.3321/j.issn:0412-1961.2003.09.005","fpage":"920","id":"d0481757-dbd4-4ba6-88f2-8a3099db97f1","issue":"9","journal":{"abbrevTitle":"JSXB","coverImgSrc":"journal/img/cover/JSXB.jpg","id":"48","issnPpub":"0412-1961","publisherId":"JSXB","title":"金属学报"},"keywords":[{"id":"80bebb16-10b7-4493-803c-19b6a184a52c","keyword":"纯铝","originalKeyword":"纯铝层"},{"id":"2bfef37a-b93c-4b19-ac41-0fbf5f0abb19","keyword":"爆炸焊","originalKeyword":"爆炸焊"},{"id":"d2583949-55ac-4494-ae54-c6669ef7dfac","keyword":"约束","originalKeyword":"约束"},{"id":"c5caf5f3-fed6-465c-8d10-212959e638bf","keyword":"韧脆转变","originalKeyword":"韧脆转变"},{"id":"7cbd0808-22cd-4944-876c-a73b473316dc","keyword":"解理","originalKeyword":"解理"}],"language":"zh","publisherId":"jsxb200309005","title":"双界面约束下纯铝韧脆转变行为的实验研究","volume":"39","year":"2003"},{"abstractinfo":"利用透射电镜(TEM)中的原位拉伸台对纯金属铝及受强度错配双界面约束的纯铝拉伸过程进行观察.结果表明:纯金属铝拉伸过程中裂端形成微孔洞后即与主裂纹连接,在界面约束条件下,裂端形成微孔后并非立即与主裂纹连通,而是在更前沿位置产生更多的微孔洞,即发生连续孔洞化.拉伸过程中,裂尖钝化与锐化的现象共存,随着中间纯铝厚度的降低,裂端发射的位错在其周围晶界形成越来越严重的塞积,大大提高了晶界及裂端前沿应力场强度,引起中间纯铝的脆化.","authors":[{"authorName":"李梁","id":"d54696a2-40d8-454e-a1a7-100b602f805e","originalAuthorName":"李梁"},{"authorName":"韩礼红","id":"a748aabc-088f-4151-9bc9-3cd0c9417f11","originalAuthorName":"韩礼红"},{"authorName":"孙军","id":"ae049ee5-a64f-4354-a569-e73e083da3f6","originalAuthorName":"孙军"}],"doi":"","fpage":"1196","id":"32896a19-8830-4eff-a4e4-b78f5a4d8d56","issue":"8","journal":{"abbrevTitle":"XYJSCLYGC","coverImgSrc":"journal/img/cover/XYJSCLYGC.jpg","id":"69","issnPpub":"1002-185X","publisherId":"XYJSCLYGC","title":"稀有金属材料与工程"},"keywords":[{"id":"b24c039f-e185-4b17-84a6-133660045268","keyword":"界面约束","originalKeyword":"界面约束"},{"id":"3dcc4b3b-5735-4e2d-a7e9-8edbdd303015","keyword":"纯铝","originalKeyword":"纯铝"},{"id":"3f8f4913-ea8f-4e8f-a191-0154a58bf9de","keyword":"TEM原位观察","originalKeyword":"TEM原位观察"}],"language":"zh","publisherId":"xyjsclygc200508005","title":"强度错配双界面约束条件下纯铝TEM原位拉伸观察","volume":"34","year":"2005"},{"abstractinfo":"目的 研究不同约束材料对激光喷丸表面强化效果的影响.方法 将激光喷丸技术应用于7075航空铝合金的表面强化处理,利用自制柔性约束、K9玻璃和水层作为激光喷丸的约束材料,对7075-T6铝合金进行激光喷丸处理,通过测量不同约束激光喷丸后的试样表面显微硬度值来衡量表面强化效果.结果 在激光能量为1.6 J、脉宽为10 ns、波长为1064nm的条件下进行单点单次冲击,自制柔性约束的表面强化效果最好,能使7075铝合金靶材的表面显微硬度值有效提升了11.62%,并且进行连续激光冲击后,其硬度值提升了18.11%;水层作为约束的表面强化效果次之,能使7075铝合金靶材的表面显微硬度值提升6.99%,容易造成水花飞溅;K9玻璃作为约束的表面强化效果最差,其表面显微硬度值仅提升了4.05%,K9玻璃在激光喷丸试验中容易破裂.结论 通过对激光喷丸试验的结果进行分析和比较,发现不同约束材料对7075铝合金表面强化效果影响的机理不同,自制柔性约束对7075铝合金激光喷丸表面强化效果最显著,且具有工程应用价值.","authors":[{"authorName":"吴江","id":"9d5d8c5e-73ff-4bb4-9fec-bf599c99fcc5","originalAuthorName":"吴江"},{"authorName":"程秀全","id":"6568e411-2205-4372-8b62-db7ad611061b","originalAuthorName":"程秀全"},{"authorName":"夏琴香","id":"63d4349b-1fc5-49d9-a9da-c10c653b5b2b","originalAuthorName":"夏琴香"},{"authorName":"李家宇","id":"99a75da5-48f7-488d-9ef4-659dd1cc4c91","originalAuthorName":"李家宇"}],"doi":"10.16490/j.cnki.issn.1001-3660.2017.03.019","fpage":"124","id":"cdd892e0-7c8c-49e4-9c48-3970da00b165","issue":"3","journal":{"abbrevTitle":"BMJS","coverImgSrc":"journal/img/cover/BMJS.jpg","id":"3","issnPpub":"1001-3660","publisherId":"BMJS","title":"表面技术 "},"keywords":[{"id":"eed90702-b8ac-4f5d-954d-09e16be3af0a","keyword":"激光喷丸强化","originalKeyword":"激光喷丸强化"},{"id":"d06ceef8-3ec9-49d2-96aa-ede91578f0c4","keyword":"表面显微硬度","originalKeyword":"表面显微硬度"},{"id":"5dacaecb-81e6-4f14-b67a-d5e9e0e6a3f0","keyword":"K9玻璃","originalKeyword":"K9玻璃"},{"id":"6d6f4ca3-4cd0-4461-954d-51e2e1422c5c","keyword":"水层","originalKeyword":"水层"},{"id":"067c87a4-1b9d-4854-83b7-f8108eed1723","keyword":"自制柔性约束","originalKeyword":"自制柔性约束层"},{"id":"7642a7cc-bef3-4f1b-85c5-66aef4e755ec","keyword":"表面强化","originalKeyword":"表面强化"}],"language":"zh","publisherId":"bmjs201703020","title":"约束材料对7075铝合金激光喷丸表面强化的实验研究","volume":"46","year":"2017"},{"abstractinfo":"在液晶显示器或硅基液晶显示器中,取向或彩色滤色膜对驱动电压的分压效应是不能忽视的.文章应用电容模型,理论上给出了液晶的分压公式和液晶的等效介电常数公式,并通过模拟计算了取向厚度、液晶厚度对液晶分压的影响.研究结果对液晶显示器的结构设计有一定的参考意义.","authors":[{"authorName":"田园","id":"0c1d6982-4e70-4d29-96cc-81a838037616","originalAuthorName":"田园"},{"authorName":"张亚星","id":"2eced632-40cd-422c-af47-60628fedde57","originalAuthorName":"张亚星"},{"authorName":"孙玉宝","id":"2c27eb51-c59c-436f-a33e-abfc68b54d9c","originalAuthorName":"孙玉宝"}],"doi":"10.3969/j.issn.1007-2780.2010.04.030","fpage":"588","id":"fdb20a23-5f9f-4895-881c-1635da738a02","issue":"4","journal":{"abbrevTitle":"YJYXS","coverImgSrc":"journal/img/cover/YJYXS.jpg","id":"72","issnPpub":"1007-2780","publisherId":"YJYXS","title":"液晶与显示 "},"keywords":[{"id":"da7f2d07-3f6d-4cd5-b57e-b3cd8b4e922b","keyword":"取向","originalKeyword":"取向层"},{"id":"38964b19-8518-4db7-92ea-042ddc720675","keyword":"液晶显示器","originalKeyword":"液晶显示器"},{"id":"2c0d72c2-546e-47ab-8a34-ffd517c8d8ff","keyword":"分压","originalKeyword":"分压"}],"language":"zh","publisherId":"yjyxs201004030","title":"取向厚度对液晶分压的影响","volume":"25","year":"2010"}],"totalpage":2903,"totalrecord":29026}