Course Description

Strength of Materials Lab, ENGR 151L

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Fundamental concepts of how objects deform or fail under loading, and related concepts by analyzing stretching, bending and torsion of beams/ rods along with their stress and strain analysis; Stress and strain analysis in pressure vessels; strength and elastic instability (buckling).
Must be taken with ENGR 151.
 

Key Information

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Credit: 0 quarter units / 0 semester units credit
UC Merced, Engineering

Course Credit:

Upon successful completion, all online courses offered through cross-enrollment provide UC unit credit. Some courses are approved for GE, major preparation and/or, major credit or can be used as a substitute for a course at your campus.

If "unit credit" is listed by your campus, consult your department, academic adviser or Student Affairs division to inquire about the petition process for more than unit credit for the course.

UC Berkeley:
Lab Section, Unit Credit

UC Davis:
Lab Section, Unit Credit

UC Irvine:
Lab Section, Unit Credit

UC Los Angeles:
Lab Section, Unit Credit

UC Merced:
Unit Credit (see your Academic Advisor)

UC Riverside:
Lab Section, Unit Credit

UC San Diego:
Lab Section, Unit Credit

UC San Francisco:
Lab Section, Unit Credit

UC Santa Barbara:
Lab Section, Unit Credit

UC Santa Cruz:
Lab Section, Unit Credit

Prerequisites

ENGR 057 Minimum Grade: C- And ENGR 045 Minimum Grade: C-

More About The Course

Must be taken with ENGR 151.

Course Creator

Sachin Goyal
Sachin Goyal is an Assistant Professor in the Department of Mechanical Engineering at the University of California, Merced. He has research interests in the areas of continuum mechanics, dynamics and controls with applications to several engineering and biological systems. He started a research program on Biomechanics and Mechanobiology at UC Merced with two ongoing research directions (http://me.ucmerced.edu/research-areas/biomechanics-and-mechano-biology):
  1. Understanding biomechanical symptoms of Parkinson's Disease from the perspective of feedback control theory
  2. Modeling constitutive laws of biological filaments from their atomistic structures
Before launching these research directions, he contributed a nonlinear computational rod model to simulate the mechanics of filament-like structures and has applied it to analyze the biologically relevant deformations of DNA. He received his B.Tech. degree (1997) in Mechanical Engineering from Banaras Hindu University (BHU), India, and his M.S. and Ph.D. degrees (2006) in Mechanical Engineering and Scientific Computing from the University of Michigan. He also has had an industrial experience at Larson and Toubro Limited, India, has held a postdoctoral research appointments with Woods Hole Oceanographic Institution (WHOI) and in Biophysics department at Emory University, has served as a faculty in the Indian Institute of Technology (IIT) at Gandhingar, India and in the Theoretical and Applied Mechanics/ Mechanical and Aerospace Engineering department at Cornell University, and has served as a technical adviser to Timetooth Technologies Pvt. Ltd., India. Sachin Goyal is an Assistant Professor in the Department of Mechanical Engineering at the University of California, Merced. He has research interests in the areas of continuum mechanics, dynamics and controls with applications to several engineering and biological systems. He started a research program on Biomechanics and Mechanobiology at UC Merced with two ongoing research directions ( ...

Sachin Goyal is an Assistant Professor in the Department of Mechanical Engineering at the University of California, Merced. He has research interests in the areas of continuum mechanics, dynamics and controls with applications to several engineering and biological systems. He started a research program on Biomechanics and Mechanobiology at UC Merced with two ongoing research directions (http://me.ucmerced.edu/research-areas/biomechanics-and-mechano-biology):
  1. Understanding biomechanical symptoms of Parkinson's Disease from the perspective of feedback control theory
  2. Modeling constitutive laws of biological filaments from their atomistic structures
Before launching these research directions, he contributed a nonlinear computational rod model to simulate the mechanics of filament-like structures and has applied it to analyze the biologically relevant deformations of DNA. He received his B.Tech. degree (1997) in Mechanical Engineering from Banaras Hindu University (BHU), India, and his M.S. and Ph.D. degrees (2006) in Mechanical Engineering and Scientific Computing from the University of Michigan. He also has had an industrial experience at Larson and Toubro Limited, India, has held a postdoctoral research appointments with Woods Hole Oceanographic Institution (WHOI) and in Biophysics department at Emory University, has served as a faculty in the Indian Institute of Technology (IIT) at Gandhingar, India and in the Theoretical and Applied Mechanics/ Mechanical and Aerospace Engineering department at Cornell University, and has served as a technical adviser to Timetooth Technologies Pvt. Ltd., India.

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