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3:00 PM
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4:00 PM
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Summer Financial Aid FAFSA Help Zoom Labs
- Location: > See description for location
- Contact: > See Description for contact information
- Description: Financial Aid Services wants to remind all students to file their FAFSA! Join Financial Aid Services for FAFSA Help Labs via Zoom on Fridays from 3-4pm for help filing your FAFSA and learning more about financial aid.
Contact Mark Yanni
myanni@umassd.edu
Join Zoom Meeting
https://umassd.zoom.us/j/97888455259?pwd=MjNiSmsvY2N0Mk1UNGhSL2ttM0g2UT09
- Topical Areas: Students, Students, Graduate, Students, Law, Students, Undergraduate, Financial Aid
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5/17
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5/31
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Blended Teaching: Designing Meaningful Content Connections
- Location: Online
- Contact: CITS Instructional Development
- Description: An engaging two-week, fully online certification course that introduces faculty to current research and best practices for blended teaching and learning. Using their own discipline-specific course materials for activities, faculty will work independently, and collaboratively with peers from across campus, and with Instructional Designers to design and build one unit of blended instruction that can be incorporated into their course(s), to enhance student engagement and meaningful content connections. This unit of instruction will meet the Quality Blended Course Review Rubric criteria and be a model that faculty can reference and replicate as they continue to develop their upcoming blended course(s) in a myCourses site.
- Link: https://instructionaldev1.sites.umassd.edu/teaching-blended/
- Topical Areas: Training, Workshop, audience: Faculty
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2:00 PM
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4:00 PM
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Mechanical Engineering MS Thesis Defense by Mr. Ross Jacques
- Location: > See description for location
- Contact: Mechanical Engineering Department
- Description: Mechanical Engineering MS Thesis Defenseby Mr. Ross Jacques
DATE:
May 19, 2023
TIME:
2:00 p.m. - 4:00 p.m.
LOCATION:
SENG-110 (Materials Science Laboratory)
TITLE:
Energy Harvesting of Flow-Induced Vibrations Using Sliding-Mode Triboelectric Nanogenerators
ABSTRACT:
This research investigates the potential of clean energy harvesting using Sliding-Mode Triboelectric Nanogenerators (S-TENGs) to convert energy from Flow-Induced Vibrations (FIV) into usable electrical energy. Triboelectric Nanogenerators have been integrated into various applications such as fabrics, jewelry, and micro-sensors. The primary focus of this study is to use S-TENGs in FluidStructure Interactions (FSI) to harvest energy from FIV by utilizing the response from FSI to initiate motion between the S-TENG plates. Considering their compatibility with easily obtainable materials, cost-effective manufacturing, and adaptability for various applications,
S-TENGs may be the next step in clean energy harvesting techniques. Traditional energy harvesting methods for S-TENGs have been predominantly mechanical, employing actuators and motors to move the electrodes. However, by incorporating fluid flow, it is now possible to harvest electrical energy from a flowing fluid, converting the original energy source into a renewable one. The FIV-based energy extraction process involves a flexibly mounted solid, triangular cylinder placed in a flowing fluid that undergoes large-amplitude flow-induced vibration. But what is the flow-induced vibration? When a flowing fluid interacts with a stationary or moving bluff body, a vortex dominated wake is formed behind it. If the structure is flexible, or flexibly-mounted, the vortex shedding in the wake of the bluff body can lead to galloping - an FIV instability observed in bluff bodies with large oscillation amplitudes normal to the flow direction at low frequencies. Here in this research, the benefits of TENGs operating at low frequencies, such as those observed in the galloping type FIV response of the triangular structure, was examined in detail. Our results indicate that by adjusting the flow velocity, contact pressure, and resistance in the electrical circuit, the FIV response can be altered, directly affecting the energy harvesting efficiency. Our results also show that an S-TENG operating under constant contact pressure exhibits different behavior when the flow velocity and circuit resistance are varied. By changing the resistance and velocity, there is an optimum efficiency and power for which this system best operates. These results demonstrate the potential of STENGs to produce usable, efficient power when set at their optimum resistance, offering a promising foundation for developing large-scale S-TENG energy harvesters capable of generating clean, renewable energy with minimal environmental impact.
ADVISOR:
- Dr. Banafsheh Seyed-Aghazadeh, Assistant Professor of Mechanical Engineering, UMassD
COMMITTEE MEMBERS:
-Dr. Caiwei Shen, Assistant Professor of Mechanical Engineering, UMassD
-Dr. Jun Li, Assistant Professor of Mechanical Engineering, UMassD
Open to the public.
Zoom Meeting ID: 920 1076 9858
Passcode: 400627
Meeting Link: https://umassd.zoom.us/j/92010769858?pwd=UjZNUHU1REI0eHV0cC96cE9ncXltdz09
For more information, please contact Dr. Banafsheh Seyed-Aghazadeh (508-999-8567)
- Topical Areas: Faculty, General Public, Staff and Administrators, Students, Students, Graduate, Students, Undergraduate, University Community, College of Engineering, Mechanical Engineering, Lectures and Seminars
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