报告时间:2019年9月24日(星期二)15:00-15:20
报告地点:机械楼214
报 告 人:Jeff Plott
工作单位:University of Michigan Ann Arbo
举办单位:机械工程学院
报告人简介:
Dr. Plott completed his undergraduate, master’s, and PhD in Mechanical engineering at the University of Michigan. Dr. Plott’s research is primarily in design and manufacturing with his PhD focusing on the additive manufacturing of soft silicone elastomers, enabling the custom manufacturing of functional and compliant silicone structures with potential use in countless medical, consumer, transportation, and building applications. Additionally, Dr. Plott designs and develops medical devices including: (1) a long-term nasophyngeal airway (NPA), (2) a wound cleaning device to minimize aerosols, (3) the clot buster mechanical thrombectomy device for stroke treatment, (4) a catheter balloon for gastroesophageal resuscitative occlusion of the aorta (GROA), (5) custom silicone CPAP/BiPAP masks for ALS patients, (6) a lacrimal stent to facilitate tear drainage, (7) a microvascular anastomosis device, (8) a tourniquet for military and civilian use, (9) a device to aid in the treatment of neuroma, and (10) a prostate biopsy needle device.
报告简介:
Dr. Plott’s final talk will be about his current areas of research, including medical device development, and tips for how to do research at the University of Michigan.
Due to the soft nature of silicone, additive manufacturing (AM) is technically challenging. The tangential and normal forces imparted by the extrusion-based AM of silicone were experimentally studied to investigate the effects of three key process parameters: volumetric flow rate, nozzle tip inner diameter, and layer height. A CFD model was also created and compared to the experimental results. The interaction between the nozzle tip and extruded silicone bead is controlled to either prevent any interaction, flatten the top surface of the extruded silicone, or immerse the nozzle in the extruded silicone. Results showed that tangential and normal forces strongly depend on this interaction. These findings create a foundational understanding of the extrusion-based AM of silicone and other soft materials. The results presented can be implemented to enable control strategies which may greatly expand the design freedoms for producing compliant, stretchable, and functional custom silicone parts.
2019-09-21
