an Erskine Fellow at the Uni- versity of Canterbury in New Zealand. His research involves the rheology of complex fluids, especially traditional and renewable energy fluids and materials, polymers, and colloids. His educational interests include developing problems from YouTube videos, active learning, learning analytics, and interactive textbooks. His interactive textbooks for Material and Energy Balances, Spreadsheets, and Thermody- namics are available from zyBooks.com. His website is: https://www.utoledo.edu/engineering/chemical- engineering/liberatore/ ©American Society for Engineering Education, 2023 Clustering of Animation View Times
Erskine Fellow at the Uni- versity of Canterbury in New Zealand. His research involves the rheology of complex fluids, especially traditional and renewable energy fluids and materials, polymers, and colloids. His educational interests include developing problems from YouTube videos, active learning, learning analytics, and interactive textbooks. His interactive textbooks for Material and Energy Balances, Spreadsheets, and Thermody- namics are available from zyBooks.com. His website is: https://www.utoledo.edu/engineering/chemical- engineering/liberatore/ ©American Society for Engineering Education, 2023 Reproducible High Reading Participation and Auto-Graded Homework
-Champaign, all in chemical engineering. From 2005 to 2015, he served on the faculty at the Colorado School of Mines. In 2018, he served as an Erskine Fellow at the University of Canterbury in New Zealand. His research involves the rheology of complex fluids, especially traditional and renewable energy fluids and materials, polymers, and colloids. His educational interests include developing problems from YouTube videos, active learning, learning analytics, and interactive textbooks. His interactive textbooks for Material and Energy Balances, Spreadsheets, and Thermodynamics are available from zyBooks.com. His website is: https://www.utoledo.edu/engineering/chemical-engineering/libe ©American
research focuses on student belonging in engineering classrooms, hands-on learning, and team/group dynamics. ©American Society for Engineering Education, 2024 Material and Energy Balances AND Character Development: an investigation of student responses to intentional virtue education in a traditional chemical engineering courseAbstractEngineering education has long held that along with cultivating engineers with solid technicalskills, programs must also develop students to be safe, ethical, and community engagedprofessionals. This has been emphasized time and again through professional organizationsacross all engineering disciplines and within the ABET accreditation structure
Teach” surveys focus on a particular core chemical engineering courseeach year and have recently covered topics of Capstone [1], Material and Energy Balances [2],Kinetics and Reactions [3], Intro Classes [4], Thermodynamics [5], Unit Operation Labs [6],Process Control [7], and Transport [8] individually. However, fundamental limitations arepresent with any survey, such as non-response bias, and misrecollection.This work serves to complement department surveys using three sources of publicly availabledata: 1. the ground truth of published course schedules; 2. Faculty numbers and position fromstaff pages on department websites; and 3. Each program’s recommended 4-year BS program,BS/MS program, and masters program. Data was collected from the 2022
the University of California, San Diego has integrated agroup project analyzing a chemical processing plant throughout the curriculum. The goal of theproject is to tie together concepts in the core courses, which can otherwise appear disconnected.Students first analyze the chemical plant in Material and Energy Balances. They then build uponthat analysis using the material they learn in Chemical Engineering Thermodynamics, ChemicalReaction Engineering, Separation Processes, Chemical Process Dynamics and Control, and,finally, in the capstone Chemical Plant and Process Design course.This paper presents quantitative and qualitative survey results from students at different stages inthe curriculum. A 5-point Likert scale was used to evaluate the
connecting representations. Students also tend to focus on thesurface features instead of the underlying scientific principles.In chemical engineering, students are introduced to block flow diagrams (BFDs), a new type ofpictorial representation of a chemical process, early in the curriculum. For example, in thesophomore-level material and energy balances, often an initial exercise is to convert a wordproblem into a simple block flow diagram. The block flow diagram consists of a series of blocksrepresenting different equipment or unit operations that are connected by input and outputstreams. Important information such as operating temperatures, pressures, and flow rates areincluded in the diagram. However, the diagram does not include any details of
. There is a needto bridge this knowledge gap in order to position each accepted student to succeed in graduatestudies.Since 2018 the department has offered a self-paced online course sequence consisting of twocourses, three credit hours each which are typically taken Fall/Spring or Spring/Summer, forstudents with a BS degree in a non-CHE science or engineering field. This two-course sequenceserves as a “bridging course” and teaches the core concepts in chemical engineering to students,covering material including material and energy balances, thermodynamics, transportphenomena, and reactor design. The course content, organization and continuous improvementhave been previously presented and documented [1-5].Now that the two-course sequence has
and academia. Othersoftware will be implemented in subsequent courses as the project progresses.The departmental learning objectives for the mass and energy balances course include not onlycontent-related skills but also specify that students “use spreadsheets (Excel) and/or an appliedmathematical software package to solve material and energy balance problems.” Complicatedsystems of equations requiring a numerical solver provide opportunity to practice these skills, butthe complexity of such problems can result in students feeling overwhelmed, especially forstudents with limited experience using software for problem-solving applications. Among asample group of students beginning the mass and energy balances course, 27 out of 78 (35%)self
directconnection between the students’ home neighborhoods and the data being collected, fostersstudent investment and curiosity in their analysis.KeywordsAir quality, modelingMotivationIn chemical engineering curricula, it can often be difficult to identify relevant and meaningfulexamples that relate beyond the realm of traditional process engineering. Environmentally-oriented coursework often employs examples within the natural world’s subsystems (i.e., theatmosphere, hydrosphere, lithosphere, and biosphere) to demonstrate principles of masstransport, material and energy balances, and chemical kinetic phenomena. Notably, climate andatmospheric systems have provided a consistently topical and well-documented source ofinformation from which inspiration for
Paper ID #42538Do Lightly-Flexible Deadlines Support Student Performance?Prof. Joshua A Enszer, University of Delaware Dr. Joshua Enszer is an associate professor in Chemical and Biomolecular Engineering at the University of Delaware. He has taught core and elective courses across the curriculum, from introduction to engineering science and material and energy balances to senior- and graduate-level electives on process safety and advanced mathematical modeling. ©American Society for Engineering Education, 2024 Do Lightly-Flexible Deadlines Support Student Performance?AbstractSince the
in chemical engineering. From 2005 to 2015, he served on the faculty at the Colorado School of Mines. In 2018, he served as an Erskine Fellow at the Uni- versity of Canterbury in New Zealand. His research involves the rheology of complex fluids, especially traditional and renewable energy fluids and materials, polymers, and colloids. His educational interests include developing problems from YouTube videos, active learning, learning analytics, and interactive textbooks. His interactive textbooks for Material and Energy Balances, Spreadsheets, and Thermody- namics are available from zyBooks.com. His website is: https://www.utoledo.edu/engineering/chemical- engineering/liberatore
rheology of complex fluids, especially traditional and renewable energy fluids and materials, polymers, and colloids. His educational interests include developing problems from YouTube videos, active learning, learning analytics, and interactive textbooks. His interactive textbooks for Material and Energy Balances, Spreadsheets, and Thermodynamics are available from zyBooks.com. His website is: https://www.utoledo.edu/engineering/chemical-engineering/libe ©American Society for Engineering Education, 2024 Building a great student chapter: Reflections on workshop activities using entrepreneurial mindsetAbstractGrowing as a student, professor, or engineer commonly involves
score), incoming declared major(which is declared at the time of matriculation), undergraduate academic performance (first-yearGPA), grades in Materials and Energy Balances (MEB), and postsecondary degree completion.The institutional data about student identity is limited to binary gender, which does notadequately capture the full spectrum of both gender identity and expression. Both gender identityand expression may be distinct from biological sex. This particular institution is predominantlywhite ( 80%) and somewhat selective (interquartile range of ACT scores is 25-31). We had accessto all student records dating back to 2011. To ensure that we had complete records for all studentsincluded in our analysis, we only included records for
obtained her BS in Chemical Engineering at NC State in 1986 and her Ph.D. in Chemical Engineering from Carnegie Mellon University in 1991. A faculty member at NC State since 2000, Dr. Bullard’s research interests lie in the area of educational scholarship, including teaching and advising effectiveness, academic integrity, chemical engineering instruction, and organizational culture.Prof. Joshua A. Enszer, University of Delaware Dr. Joshua Enszer is an associate professor in Chemical and Biomolecular Engineering at the University of Delaware. He has taught core and elective courses across the curriculum, from introduction to engineering science and material and energy balances toDr. Allison Godwin, Purdue University
documented use of a TE for undergraduate ChE education. Due tothis, the student’s perceived time commitment to the course and learning experience fromassignments in a TE will also be investigated to determine for prospective practitioners whatholistic outcomes can arise in students when this strategy is implemented.METHODSCourse description and student population Transport Processes I – Momentum Transfer is a 3-credit hour course that ChE-majoringstudents enroll in after their foundational courses of material and energy balances andthermodynamics. During this study, a student cohort consisting of one section was co-instructedby two of the authors (SK & SRC) in the Fall 2023 semester. Students were taught primarilythrough didactic
). Capstone at NortheasternUniversity is a project-based course where teams design a chemical process for a product orsystem with consideration of public health, safety, and welfare, as well as global, cultural, social,environmental, and economic factors. All projects require applications of chemical engineeringcurriculum such as material and energy balances, kinetics, thermodynamics, and mass and heattransport and using the engineering design process to come up with a business plan, considermultiple designs, and come up with a final detailed design process. The design is validated withproof-of-concept data from a prototype, experiments, or simulation of the process to show thedesign is feasible and use that data to improve the design. Teams present
) Static Scripts Source (.m / .py) Resource Description (.ipynb) OtherComputer Aids for Chemical Engineering (CACHE)chemical engineering teaching resources categorized bysubject including material and energy balances, fluid X X X