更新组内成员: Binjiang Lv| Post doctorate

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联系方式 <div class="gr_information">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Mail： lbj818@163.com<ul><p>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Tel： 15263035641</p><p>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp; Office：301， Engineering Training C

个人简介 <p>&nbsp;&nbsp;&nbsp;&nbsp; Bin-Jiang Lv, is a PhD in the School of Mechanical Engineering at QUT. His current research is the development of new Mg materials and their deformation process. Dr. Lv has been granted by Shandong Provincial Natural Science Foundation (ZR2016EMQ08), and participates in a Natural Science Foundation of China (51505245). He has published 15 peer-reviewed papers on journals such as MSEA、M&amp;D、JMEP、etc, and 11 of them were indexed by SCI.</p>

研究课题 <h1>研究方向</h1><p><span>1. </span>镁合金新材料开发及变形工艺研究</p><p><span>2. </span>镁合金摩擦磨损性能研究</p><h1>研究课题</h1><p><span>1. </span>山东省自然科学基金青年基金项目，<span>ZR2016EMQ08</span>，基于孪晶动态再结晶机制开发低成本可高速挤压变形镁合金，<span>2017/11-2019/10</span>，在研，主持。</p><p><span>2. </span>国家自然科学基金青年基金项目，<span>51505245</span>，基于运动合成的活塞异形销孔加工新原理及关键技术研究，<span>2016/01-2018/12</span>，在研，参加。</p><p><br/></p>

研究成果 <h1>代表论文</h1><p><span>1. </span>吕滨江，彭建，禇忠<span>. </span>铸造冷却方式对<span>Mg-4.4Zn-0.3Zr-0.4Y</span>挤压态合金组织及性能的影响<span>. </span>稀有金属材料与工程，<span>2017</span>，<span>46</span>（<span>1</span>）：<span>189~194 </span>（<span>SCI</span>）</p><p><span>2. </span>吕滨江，彭建，梁鹏，王进<span>. LPSO</span>堆垛结构转变对挤压态<span>Mg-2.0Zn-0.3Zr-5.8Y</span>镁合金组织性能的影响<span>. </span>稀有金属材料与工程，<span>2016</span>，<span>45</span>（<span>11</span>）：<span>2861~2866 </span>（<span>SCI</span>）</p><p><span>3. </span>吕滨江，彭建，梁鹏，王进<span>. </span>冷却速率对<span>Mg-4.4Zn-0.3Zr-0.4Y</span>变形镁合金组织和性能的影响<span>. </span>材料工程，<span>2016</span>，（<span>09</span>）：<span>82~88 </span>（<span>EI</span>）</p><p><span>4. Bin-Jiang Lv</span>，<span>Jian Peng</span>，<span>Zhong Chu. The Effect of Icosahedral Phase on Dynamic Recrystallization Evolution and Hot Workability of Mg-2.0Zn-0.3Zr-0.2Y Alloy. Journal of Materials Engineering and Performance</span>，<span>2015</span>，<span>24</span>（<span>9</span>）：<span>3502~3512 </span>（<span>SCI</span>）</p><p><span>5. Bin-Jiang Lv</span>，<span>Jian Peng</span>，<span>Yi Peng</span>，<span>Ai-Tao Tang</span>，<span>Fu-Sheng Pan. Mechanical properties and energy absorption of extruded Mg–2.0Zn–0.3Zr alloy with Y addition. Rare Metals</span>，<span>2015</span>，<span>34</span>（<span>5</span>）：<span>314~323 </span>（<span>SCI</span>）</p><p><span>6. </span>吕滨江，彭建，韩韡，汤爱涛，潘复生<span>. </span>水冷对普通铸造<span>Mg-Zn-Zr-Y</span>镁合金准晶相形成的影响及铸态组织研究<span>. </span>稀有金属材料与工程，<span>2014</span>，<span>43</span>（<span>7</span>）：<span>1643~1648 </span>（<span>SCI</span>）</p><p><span>7. Bin-Jiang Lv</span>，<span>Jian Peng</span>，<span>Li-Li Zhu</span>，<span>Yong-Jian Wang</span>，<span>Ai-Tao Tang. The effect of 14H LPSO phase on dynamic recrystallization behavior and hot workability of Mg–2.0Zn–0.3Zr–5.8Y alloy. Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing</span>，<span>2014</span>，<span>599</span>：<span>150~159 </span>（<span>SCI</span>）</p><p><span>8. Bin-Jiang Lv</span>，<span>Jian Peng</span>，<span>Yong-Jian Wang</span>，<span>Xiao-Qin An</span>，<span>Li-Ping Zhong</span>，<span>Ai-Tao Tang</span>，<span>Fu-Sheng Pan. Dynamic recrystallization behavior and hot workability of Mg–2.0Zn–0.3Zr–0.9Y alloy by using hot compression test. Materials &amp; Design</span>，<span>2014</span>，<span>53</span>：<span>357~365 </span>（<span>SCI</span>）</p><p><span>9. Bin-Jiang Lv</span>，<span>Jian Peng</span>，<span>Yi Peng</span>，<span>Ai-Tao Tang</span>，<span>Fu-Sheng Pan. The effect of LPSO phase on hot deformation behavior and dynamic recrystallization evolution of Mg–2.0Zn–0.3Zr–5.8Y alloy. Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing</span>，<span>2013</span>，<span>579</span>：<span>209~216 </span>（<span>SCI</span>）</p><p><span>10. Bin-Jiang Lv</span>，<span>Jian Peng</span>，<span>Da-Wei Shi</span>，<span>Ai-Tao Tang</span>，<span>Fu-Sheng Pan. Constitutive modeling of dynamic recrystallization kinetics and processing maps of Mg–2.0Zn–0.3Zr alloy based on true stress–strain curves. Materials Science and Engineering A-Structural Materials Properties Microstructure and Processing</span>，<span>2013</span>，<span>560</span>：<span>727~733 </span>（<span>SCI</span>）</p><p><br/></p>

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