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    Project Based Learning For Earthquake Engineering

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    ஆனந்த் கிருஷ்ணன்
    This document describes several project-based learning projects implemented in structural engineering courses to enhance student learning. The projects aim to replace traditional lecture with hands-on learning that simulates real-world engineering work. Graduate students model concrete columns and conduct literature reviews on drift demands. Undergraduate students design timber retrofits, evaluate a parking garage for code compliance, and more. The projects integrate seismic concepts, develop skills like teamwork and communication, and provide differentiated learning experiences.

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    Project Based Learning For Earthquake Engineering

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    ஆனந்த் கிருஷ்ணன்
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    This document describes several project-based learning projects implemented in structural engineering courses to enhance student learning. The projects aim to replace traditional lecture with hands-on learning that simulates real-world engineering work. Graduate students model concrete columns and conduct literature reviews on drift demands. Undergraduate students design timber retrofits, evaluate a parking garage for code compliance, and more. The projects integrate seismic concepts, develop skills like teamwork and communication, and provide differentiated learning experiences.

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    Mcmullin

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    326.07Mcmullin

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    This document describes several project-based learning projects implemented in structural engineering courses to enhance student learning. The projects aim to replace traditional lecture with hands-on learning that simulates real-world engineering work. Graduate students model concrete columns and conduct literature reviews on drift demands. Undergraduate students design timber retrofits, evaluate a parking garage for code compliance, and more. The projects integrate seismic concepts, develop skills like teamwork and communication, and provide differentiated learning experiences.

    Copyright:

    © All Rights Reserved
    Download as PDF, TXT or read online from Scribd
    Download as pdf or txt
    58 views1 page

    Project Based Learning For Earthquake Engineering

    Uploaded by

    ஆனந்த் கிருஷ்ணன்
    This document describes several project-based learning projects implemented in structural engineering courses to enhance student learning. The projects aim to replace traditional lecture with hands-on learning that simulates real-world engineering work. Graduate students model concrete columns and conduct literature reviews on drift demands. Undergraduate students design timber retrofits, evaluate a parking garage for code compliance, and more. The projects integrate seismic concepts, develop skills like teamwork and communication, and provide differentiated learning experiences.

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    of 1

    Dr. Kurt M.

    McMullin
    San Jos State University
    Cecilia Luu
    San Jos State University

    PROJECT BASED LEARNING FOR EARTHQUAKE ENGINEERING

    Objective
    The objective is to design projects for students to complete in structural engineering
    design courses that:
    Require student learning of course content to allow for completion of project.
    Enhance interaction of student teams to develop collaborative work skills and improve
    communication.
    Incorporate workplace skills of team-work, communication, project management, and time
    management.

    IMPLEMENTATION OF SEISMIC ISSUES INTO SENIOR


    AND GRADUATE LEVEL STRUCTURAL ENGINEERING COURSES

    Concrete Column Modeling

    Graduate Level 6 week project

    Students use two methods to model the monotonic nonlinear behavior of a concrete
    column:
    Concentrated hinge model prescribed by FEMA-356; and
    Fiber-based hinge model based on established uniaxial behavior for the steel and
    concrete fibers
    The results of the analytical model are compared to test results obtained for the cyclic
    testing of columns in past NEES projects.

    Simulate the work environment of engineering companies.


    Replace traditional lecture delivery of content.

    Underlying Pedagogy
    Educational research indicates that:
    traditional engineering education, dominated by lecture, is not serving engineering students well;
    the majority of engineering students are active and sensory learners;
    inquiry-based learning promotes active engagement and deeper understanding;
    inquiry-based learning allows for differentiated learning since students can control and pace the
    direction of their work.

    Specimen 2-1 at Purdue University

    San Jos State University

    The goals of the projects are to:


    Integrate seismic issues into classroom instruction
    Support inquiry and active learning in engineering courses
    Provide a mechanism for students to explore simplified examples of complex issues
    Project based learning allows:
    Differentiated learning styles and background knowledge.
    Flexible schedules and geographically dispersed student participants.
    Strengths that some students possess that may not be necessary for content of course (drafting
    skills, report organization, online search capabilities.
    Addresses issue of Why are students not ready for prime time? (which means why do companies need
    to invest so much effort=money in training entry-level engineers):
    Ability to convert 2D drawings into a 3D object.
    Ability to identify and extract critical information from a complex blueprint.
    Ability to see the Big Picture of how each component contributes to a complex system.
    Ability to recognize the importance of their work and the criticality that it be done correctly.
    Ability to ask questions to discover the critical information that they need (rather than having it
    presented to them in an easy-to-use format).
    Ability to evaluate an existing structure as opposed to design of new construction that is usually
    emphasized in school.
    Ability to summarize and present their work in a professional manner.
    Ability to incorporate feedback into the improvement of their work.
    Ability to see projects as long-term multi-revision collaborative process as opposed to weekly
    assignments that are graded but not revised.

    Module Development
    Steps in module development:
    attend experimental team meetings to understand test set up and provide input on
    data and visual needs;
    select test concepts and results best suited for integrating into courses;
    define audience (undergraduate/graduate) and develop learning outcomes;
    specify module characteristics (e.g. on-line or paper, length, analysis software, etc.);
    research and summarize theoretical basis of module;
    visit test facility;
    obtain data as it becomes available and integrate into module;
    compile drawings, photographs, and video clips relevant to module;
    create lessons, assessment activities, and documentation;
    pilot module in courses at several universities,
    disseminate modules

    The illustration shows the development of the experimental


    test specimen from the prototype structure. This illustrates
    to students the engineering process of simplifying complex
    structures for analytical modeling and experimental testing.
    Students need to recognize that boundary conditions,
    loading sequences, and specimen construction are based
    on real life structural behavior.

    Drift Demand Research Paper

    Uniaxial stress-strain relationship based on Mander et al. for


    nonlinear behavior of concrete columns

    Funded by
    NATIONAL SCIENCE
    FOUNDATION
    Timber Soft-Story Structural Retrofit
    Undergraduate Senior Level
    9 week project

    Student teams design a seismic retrofit scheme for a soft-story woodframe


    multi-story, multi-unit residential structure.
    Students provided with general architectural drawings of a hypothetical
    structure, general and specific requirements of their scope of work.
    Students required to evaluate strength of existing beams for gravity
    loading (content requirement of course).
    Students required to evaluate strength of existing shear wall system at
    Ground Level (introduction to existing estimates of extant materials from
    FEMA-356 document).
    Students required to design a suitable retrofit of plywood walls at
    Ground Level.
    Students skills enhanced:
    Understanding of load path and construction of woodframe stuctures.
    Understanding of seismic vulnerability of existing structures.
    Design vs analysis skills.
    Terminology of retrofit and structural vocabulary.
    Blueprint reading and 3D visualization.
    Public policy issues with mandatory retrofit ordinances.
    Project structure:
    Instructor provides basic content and background material
    Draft submittals every five weeks to allow for feedback and maintaining
    timely progress of work.
    Instructor meets with groups for 15-minute discussions (similar to project
    team meeting for coordination of project between project engineer,
    senior engineers, design engineers in professional firm.)
    Individual team members accountable for all content issues on
    upcoming exams.
    Final project reviewed for technical accuracy, completeness and ability
    of students to present their work in a professional manner.
    Poster session required with final submittal to enhance that students are
    capable of discussing their work, summarizing the main points,
    presenting their work graphically, responding to questions professionally.

    Graduate Level 15 week project

    Students conduct a literature review about the expected drift that structures may occur in a future earthquake.
    All students given a general topic (drift demands for structures)
    Each student must develop a unique hypothesis to test
    Students collect data from published studies completed by other researchers (NEES shake table tests,
    SAC Joint Venture analytical studies, recorded building motions from CSMIP)
    Students can collaborated on locating and evaluating data, suitable methods of presenting data, writing
    skills, citation and reference list development.
    Each student required to write a ten-page research paper about the results of their research.
    Builds a database of research over time when all students required to present their results in a common
    format (floor plans, tabulated data with specified metadata)
    Students skills enhanced:
    Locating and evaluating the suitability of published research reports.
    Analyzing data presented in report and converting to a usable form for their research (i.e. converting
    graphed story displacements to inter-story drift ratios.
    Improved grammatical structure and organization of their paper.
    Project structure:
    Instructor provides common terminology (global drift, inter-story drift, drift ratio)
    Multiple drafts reviewed with appropriate feedback.
    Students peer review each others drafts to provide feedback.
    Final paper graded by instructor for content and writing skills.
    Paper meets University Graduate Writing Requirement:
    Meets one requirement for students to graduate.
    Replaced prior option for students to choose their own topic
    Too much time choosing the best topic for paper.
    Allows instructor to provide common content to all students (and examine students on such content)

    Parking Garage Evaluation


    Undergraduate Senior Level
    2 week project
    Student teams evaluate a parking garage on campus for seismic separation
    required by current building code.
    Students provided with scope of work and estimates of expected lateral
    drift of buildings.
    Students required to measure existing structure, seismic separation, and
    determine if structure is shear wall or moment frame.
    Hands-on students taken to site during class time, pace spacing of
    columns, observe how garage is assembly of independent structures.
    Teams need to sketch floor plan, work with incomplete data and
    estimated results.
    Final report is to be a business letter format discussing their estimated
    code compliance.

    Acknowledgement
    Some projects presented in this poster were developed with sponsorship by
    the National Science Foundation (NSF) under Grant No. 619157. Release
    time to develop projects has been provided by San Jose State University.
    Any opinions, findings, conclusions, or recommendations expressed in this
    report are those of the participants, and do not necessarily represent the
    official views, opinions, or policy of these sponsors.

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