THE MINH NGUYEN 1305 Ordean Court, ENGR 242 Work: 218-726-7944 University of Minnesota Duluth Cell: 419-280-0980 tmnguyen@d.umn.edu CURRENT POSITION Visiting Assistant Professor at the Department of Mechanical and Industrial Engineering, Swenson College of Science and Engineering, University of Minnesota Duluth (UMD), Duluth, Minnesota, USA. EDUCATION Ph.D. M.S. B.S. August 2009, The University of Toledo, Toledo, Ohio Mechanical Engineering (Overall GPA: 3.83/4.0) Dissertation: A novel semi-active magnetorheological mount for vibration isolation Advisor: Dr. Mohammad Elahinia May 2006, The University of Toledo, Toledo, Ohio Mechanical Engineering (Overall GPA: 3.79/4.0) Thesis: Semiactive noise and vibration isolation for Hydraulic Hybrid Vehicles Advisor: Dr. Mohammad Elahinia Outstanding Master s Thesis Award from Mechanical, Industrial and Mfg. Eng. Department May 2004, The University of Oklahoma, Norman, Oklahoma Mechanical Engineering (Overall GPA: 3.63/4.0) FIELDS OF RESEARCH INTEREST Dynamic system modeling and control, automation, robotics Mechanics, kinematics, machine design Smart materials and mechanisms, intelligent actuation and sensing Noise, vibration and harshness (NVH) Sustainable Technologies: hybrid vehicles, offshore wind turbines, solar panel Biomedical applications of smart materials TEACHING EXPERIENCE INSTRUCTOR at UMD for O SYSTEM DYNAMICS AND CONTROL (FALL 09, SPRING and FALL 10, FALL 11) O CONTROLS AND KINEMATICS LAB (FALL 11) O CAD/CAM (SPRING 11) O MACHINE DESIGN (SPRING 11) O INTRO TO SOLID MODELING (FALL 11) ASSIST in DEVELOPMENT of the course SMART MATERIALS at UMD (SPRING 10) Teaching assistant for Engineering Statics and Thermodynamics (Fall 04), Control System Design (Spring 05) Substitute instructor for Vibration and Control, Advanced Dynamic classes (Fall 08, Spring 09) INTELLECTUAL CONTRIBUTIONS INVENTION DISCLOSURE: Nguyen, The Minh Magnetorheological Fluid Valve, Provisional Patent Application, June 2010. Elahinia, M. and Nguyen, T., Mixed-mode semiactive magnetorheological mount to the University of Toledo s Office of Research Development for review by the Patent Commercialization Committee, Jan. 2009. Nguyen, T. M. - 1
JOURNAL ARTICLES Nguyen, T. M. and Elahinia, M. H., Vibration Isolation for Hydraulic Hybrid Vehicles, Journal of Shock and Vibration, 15(2) February 2008, pp. 193-204. Nguyen, T. M., Ciocanel, C., and Elahinia, M. H.: A squeeze-flow mode magnetorheological mount: design, modeling, and experimental evaluation. Journal of Vibration and Acoustics, accepted for publication. Wang, S., Nguyen, T. and Elahinia, M., Displacement and force control with a mixed-mode MR mount, Journal of Shock and Vibration, in review. CONFERENCE PAPERS: Nguyen, T. M. and Elahinia, M. H. A 6-DOF vibration isolation system for Hydraulic Hybrid Vehicles, 2006 SPIE Smart Structures and Materials, March, 6-10, 2006, San Diego, California. Nguyen, T., and Elahinia, M. H., Nonlinear Control of a Magnetorheological (MR) Mount for Hydraulic Hybrid Vehicles, Eleventh Conference on Nonlinear Vibrations, Stability, and Dynamics of Structures, August, 13-17, 2006, Blacksburg, Virginia. Ciocanel, C., Nguyen, T., Elahinia, M. H. and Naganathan, N. G., On the Design of a Combined Squeeze- Flow Mode Magnetorheological Fluid Mount, SPIE Smart Structures and Materials, March 14-22, 2007, San Diego, California. Nguyen, T., Ciocanel, C., and Elahinia M. H., Performance of an Adaptive Magnetorheological Fluid Mount, ASME International Mechanical Engineering Congress, November 11-15, 2007, Seattle, Washington. Nguyen, T., Ciocanel, C., and Elahinia M. H., Parameter optimization in designing an MR mount. Proceedings of 15 th International Congress on Sound and Vibration ICSV15, 6-10 July 2008, Daejeon, Korea. Nguyen, T., Ciocanel, C., and Elahinia M. H., Analytical modeling and experimental validation of a magnetorheological mount, SPIE Proceedings vol. 7288, Active and Passive Smart Structures and Integrated Systems 2009. Nguyen, T., Ciocanel, C., and Elahinia M. H., A Magnetorheological Mount for Hydraulic Hybrid Vehicles, Proceedings of 2009 Conference on Adaptive Structures and Intelligent Systems (SMASIS 2009), September 21-23, 2009, Oxnard, California. Anderson, W., Elahinia, M. and Nguyen, T., Vibration Mitigation With A Multi-axial Magnetorheological Mount, Proceedings of 2009 Conference on Adaptive Structures and Intelligent Systems (SMASIS 2009), September 21-23, 2009, Oxnard, California. GRANT PROPOSALS Elahinia, M. H., Ciocanel, C. and Nguyen, T. M., An active magnetorheological mount, submitted to Honda Initiation Grant, July 2006. Status: declined (top 25 finalists). Elahinia, M. H. and Nguyen, T. M., Reducing Noise and Vibration of Hydraulic Hybrid and Plug-In Hybrid Electric Vehicles-Phase II Control of a Single-Axis MR Mount, submitted to University of Toledo University Transportation Center (UT UTC), May 2009. Status: funded. Elahinia, M. H. and Nguyen, T. M., A Multi-Axial Wide Frequency Semi-active Magnetorheological Mount for use in Hydraulic Hybrid and Plug-In Hybrid Electric Vehicles, submitted to University of Toledo University Transportation Center (UT UTC), May 2009. Status: declined. Elahinia, M. H. and Nguyen, T. M., A Wide Bandwidth Vibration Isolator for use in Hybrid and Plug-In Vehicles, submitted to Michigan Ohio University Transportation Center (MIOH UTC), June 2009. Status: declined. Nguyen, T. M. - 2
RESEARCH ACTIVITIES Master s Thesis: Semiactive Noise and Vibration Isolation for Hydraulic Hybrid Vehicles This research investigated the vibration problem of Parallel Hydraulic Hybrid Vehicles (HHV). Since the hydraulic subsystem was coupled directly to the driveshaft of the vehicle, the driveshaft became the vibration transfer path. Therefore, the powertrain of the parallel HHV was modeled in SimMechanics to investigate the vibration transmission. All the mountings were considered semiactive with controllable stiffness and damping. Appropriate configurations of mountings and connections between the hydraulic subsystem to the frame were suggested by this study. Doctoral Dissertation: A novel semiactive magnetorheological mount (MR) for vibration isolation This research is to develop a hydraulic powertrain mount (i.e. engine, transmission, pump/motor mounts) using magnetorheological (MR) fluid. This type of semiactive mounts is suitable for modern vehicles equipped with advanced technologies such as variable cylinder management or hybrids. MR fluids are smart fluids that can develop yield stress when a magnetic field is present. The MR mount employs the flow mode and the squeeze mode of the MR fluids. Each of the modes is controlled individually, so the potential contribution of each mode to the mount characteristics is maximized. The mount is designed in such a way that the operation of one mode does not interfere that of the other. The mount can operate with single modes or combined mode (or mixed-mode). These options of the operation modes allow the user to have large envelope of the stiffness and damping provided by the MR mount. One can use very high stiffness and damping to mitigate the shock loads, or various combinations of stiffness and damping for harmonic vibration isolation. Postdoctoral Research: Advanced magnetorheological (MR) fluid valve This research looks particular into reducing the amount of MR fluid used in semiactive devices. Regularly, the device is filled with MR fluid but the activated MR fluid is only within the flow channel where the electromagnet is located. In this design, the MR fluid is enclosed in a flexible pocket located inside the flow duct. When magnetic field is zero, the MR pocket is soft, and the flow (of any kind of fluids/gases) happens easily. As soon as the magnetic field is turned on, the MR pocket is hard, and the flow is restricted by the field-induced yield stress developed in the MR pocket. By varying the magnetic field strength, the flow rate is precisely controlled. That can be translated into controllable damping if this valve is used in engine mounts or shock absorbers. With small active MR fluid is enclosed in the pocket, the cost for MR fluid is significantly reduced for the MR devices. Research Projects in Graduate School: o Hydraulic Hybrid Vehicle noise and vibration test (at EPA facility in Ann Arbor, MI): This project fabricated a Hydraulic Hybrid Vehicle chassis from a Ford Expedition frame and a hydraulic subsystem including the pump/motor, accumulators and the hoses/pipes. The chassis was tested for noise and vibration characteristics of the HHV. o Hydraulic Hybrid Vehicles simulation for noise and vibration characteristics: A series HHV was modeled in Imagine.Lab (AMESim) with a simplified vehicle components and a detailed hydraulic pump/motor. The pump/motor was the main source of noise and vibration due to the pressure ripples it produced during its operation. o Shock mount designs for fuel cell in a hydrogen vehicle: The fuel cell and its mountings were modeled in simulated in SolidWorks and COSMOS for its motion response. Stiffness and damping of the shock mounts were suggested to keep the acceleration of the fuel cell within the allowable range as the vehicle ran through rough terrains. o Energy harvest using piezoelectric bimorphs: The energy harvester resembled a wind mill with a big fan blade to convert the wind power to reciprocating motion. This reciprocation provided the excitation to the piezoelectric beam. Piezoelectric beam was constructed from Macro Fiber Composites (MFC), which were piezoelectric devices. This beam bent and produced electricity while vibrating under the excitation from wind motion. o Robotic actuation using shape memory alloy: Collaborate in developing the biped robot in SimMechanics simulation and actual prototype. KEY TAKEN COURSES Smart Materials, 4 Control Courses (Control System Design, Classic/Nonlinear/Optimal Control), Advanced Dynamics, Dynamics of Structures, Advanced Vibration, Advanced Mechanics of Materials, Elasticity, Continuum Mechanics, Grant Proposal Writing (Full transcripts available upon request) Nguyen, T. M. - 3
PROFESSIONAL MEMBERSHIPS AND SERVICE SESSION ORGANIZER for SMASIS 2009 REVIEWER for Journal of Intelligent Material Systems and Structures, Journal of Sound and Vibration, ASME Journal of Dynamic Systems, OEPT 2009, IMECE 2006, IDETC/CIE 2008 Society of Automotive Engineers (SAE) American Society of Mechanical Engineers (ASME) American Society of Engineering Education (ASEE) TECHNICAL SKILLS MATLAB/Simulink (mechanical, electrical, hydraulic system modeling) MATLAB programming dspace (modeling and control) CAD software/tools: Solidworks, ProEngineering, Catia Analysis software/tools: COSMOS (Works, Motion, Magnetic), ProMechanica (dynamics), MSC.ADAMS (dynamics) LMS software/tools: Virtual.Lab (vibration and acoustic modeling), Test.Lab (vibration and acoustic testing), Imagine.Lab (electric, hydraulic, mechanical system modeling) FEA/FEM software/tools: COMSOL, ABAQUS, FEMM (magnetic finite element method modeling) Machining mechanical parts OTHER SKILLS Microsoft Office, website design, computer configure and repair Bilingual: English and Vietnamese Strong oral and writing communication skills, leadership and teamwork OTHER EXPERIENCES MENTOR for FSAE 2009-2012 TEAM, BATTLEBOTS 2010-2011 TEAM at UMD LEADER OF NOISE AND VIBRATION INVESTIGATION TEAM within the Hydraulic Hybrid Vehicles research group at University of Toledo Research committee representative of the UT Graduate Student Association 2007-2008 Shift manager at a Magic Wok Asian cuisine restaurant 2004-2005: manage 4-8 employees Real Estate Office Assistant from February 2003 to July 2004 Employee at Couch Cafeteria at University of Oklahoma from September 2001 to May 2004 Volunteer Tutor from Spring 2001 to Spring 2003 Vice President of Society of Vietnamese Students at University of Oklahoma 2003 HONORS Who s Who in America Edition 2009 MIME DEPARTMENT OUTSTANDING MASTER S THESIS AWARD Spring 2006, the University of Toledo The University of Oklahoma President s Honor Roll (Spring 2001) College of Engineering Dean s Honor Rolls (Fall 2000 Spring 2004), University of Oklahoma Mechanical Engineering Faculty and Staff Scholarship 2002, University of Oklahoma VISA STATUS J-1 directly convertible to H1B with support from the employer, not subject to 2-year home residency rule. Nguyen, T. M. - 4
REFERENCES Dr. Mohammad Elahinia Associate Professor, Mechanical, Industrial and Manufacturing Engineering Department University of Toledo 2801 W Bancroft St., Mailstop 312 Toledo, OH 43606 Phone: (419) 530-8224 Email: mohammad.elahinia@utoledo.edu Dr. Walter Olson Professor and Graduate Program Director, Mechanical, Industrial and Manufacturing Engineering Department University of Toledo 2801 W Bancroft St., Mailstop 312 Toledo, OH 43606 Phone: (419) 530-8227 Email: walter.olson@utoledo.edu Dr. Constantin Ciocanel Assistant Professor, Mechanical Engineering Department Northern Arizona University PO Box 15600 Flagstaff, AZ 86011-5600 Phone: (928) 523-2439 Email: constantin.ciocanel@nau.edu Dr. Ryan Rosandich Associate Professor and Department Head, Department of Mechanical and Industrial Engineering University of Minnesota Duluth 1305 Ordean Court, Voss Kovach Hall 105 Phone: (218) 726-7226 Email: rrosandi@d.umn.edu Dr. Daniel Pope Associate Professor, Department of Mechanical and Industrial Engineering University of Minnesota Duluth 1305 Ordean Court, Voss Kovach Hall 105 Phone: (218) 726-6685 Email: dpope@d.umn.edu Nguyen, T. M. - 5