Robotic milling for rapid ceramic pototyping 被引量：2

Robotic milling for rapid ceramic pototyping

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摘要 Robotic milling is a developing method for rapidly producing prototypes and parts, but the application is limited for materials such as wax, wood, plastic and light metal, etc. The reason for this is because of the robotic weak rigidity. In this paper, a method of robotic milling for ceramic prototyping is developed, one that has been successfully applied in a new rapid hard tooling technology-Direct Prototype Spray Tooling. At first, the appropriate ceramic materials mixed with metal powder are confirmed for the robotic milling and the following plasma spraying process. Then the 6 - DOF robotic milling paths are extracted from the NC code and transformed into the robotic JBI type file, the NC code generated through the general CAD/CAM software such as UG -NX. Finally, the robotic milling characteristics such as moving path accuracy and milling force are tested to find the best milling parameters and to ensure the executable, accurate and efficient ceramic prototype milling technology. The development of this method not only broadens the robotic milling material range but also extends the rapid prototyping fields. It can also be used for producing ceramic parts that are difficult to machine. Robotic milling is a developing method for rapidly producing prototypes and parts, but the application is limited for materials such as wax, wood, plastic and light metal, etc. The reason for this is because of the robotic weak rigidity. In this paper, a method of robotic milling for ceramic prototyping is developed, one that has been successfully applied in a new rapid hard tooling technology—Direct Prototype Spray Tooling 1 . At first, the appropriate ceramic materials mixed with metal powder are confirmed for the robotic milling and the following plasma spraying process. Then the 6-DOF robotic milling paths are extracted from the NC code and transformed into the robotic JBI type file, the NC code generated through the general CAD/CAM software such as UG-NX. Finally, the robotic milling characteristics such as moving path accuracy and milling force are tested to find the best milling parameters and to ensure the executable, accurate and efficient ceramic prototype milling technology. The development of this method not only broadens the robotic milling material range but also extends the rapid prototyping fields. It can also be used for producing ceramic parts that are difficult to machine.

作者韩光超张海鸥王桂兰

机构地区 State Key Lab. of Plastic Forming Simulation and Die & Mould Technology

出处《Journal of Harbin Institute of Technology(New Series)》 EI CAS 2005年第6期674-679,共6页 哈尔滨工业大学学报（英文版）

基金 SponsoredbytheMinistryofScienceandTechnologyoftheChineseGovernmentandtheNationalNaturalScienceFoundationofChina(GrantNo.2001AA421150and50075032).

关键词 robot MILLING ceramic prototyping milling characters 陶瓷原型快速原型法机器人磨粉直接原型喷雾加工

分类号 TG249 [金属学及工艺—铸造]

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相关文献

参考文献6

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同被引文献16

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引证文献2

1韩光超,张海鸥,王桂兰.面向金属模具快速制造的机器人成型加工系统[J].机器人,2006,28(5):515-518. 被引量：10
2韩光超,张海鸥,王桂兰.面向复杂形状型腔的机器人多轴成型加工[J].锻压技术,2007,32(4):49-51. 被引量：2

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2韩光超,孙明,张海鸥,王桂兰.基于CAM的机器人抛光轨迹规划[J].华中科技大学学报（自然科学版）,2008,36(5):60-62. 被引量：11
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Journal of Harbin Institute of Technology(New Series)

2005年第6期

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Robotic milling for rapid ceramic pototyping 被引量：2

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