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1. Adaptive learning environment for high value manufacturing (HVM) geared towards energy industry

   https://doi.org/10.18260/p.26516  

   Nepal, B. ( January 2016 , ASEE annual conference)

   This paper presents a project framework for the development of an adaptive learning environment to provide a wide range of students with the skills necessary to work in high value manufacturing (HVM) aimed at the energy industry. More specifically, it discusses a HVM certificate program being developed at Houston Community College (HCC) in collaboration with Texas A&M University (TAMU). The aim of the project is to create a sustainable certificate program in HVM that provides multiple pathways for community college students while meeting the critical workforce needs of a vital industry in Texas. The novelty of the certificate program includes innovative pedagogical methods, such as competency-based learning and skills need assessment and provision through online learning modules is presented; this allows students an adaptive and personalized education in this needed area. Upon completion of the certificate program, the community college students will have multiple pathways including: a) an A.S. at the Community College; b) transfer to four year institution; and c) return to industry to join the workforce. By incorporating a new co-educational paradigm between the community college and the university, as opposed to traditional articulation agreements, this project provides a novel pathway for community college students to transition to a four-year degree program. It also incorporates a new method for trying to ensure that community college students who matriculate to partner 4-year institutions receive reverse transfer credit for their associate degrees at their home community college. Furthermore, HVM modules are developed for high school students that are aligned with the Next Generation Science Standards. 

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2. Board 272: Engineering Pathways for Appalachian Youth: Design Principles and Long-term Impacts of School-Industry Partnerships

   https://doi.org/10.18260/1-2--42822  

   Schilling, Malle ; Grohs, Jacob ( June 2023 , ASEE Conferences)

   Broadening participation in the skilled technical workforce is a national priority given strong evidence of growing critical vacancies in engineering coupled with the urgent need for this workforce to better reflect the rich diversity of the nation. Scholars and activists often call for increased focus on education access, quality, and workforce development among rural Appalachian communities, noting that students from these communities are under-represented in higher education generally, and engineering careers specifically. Investing in preK-12 education, engaging youth as valued members of their communities, and cultivating workforce opportunities such as in advanced manufacturing have all been highlighted by the Appalachian Regional Commission as vital to strengthening economic resilience. However, scaffolding engineering and technical career pathways for Appalachian youth at scale in the context of broader systemic issues is challenging. Past research on the career choices of Appalachian youth show that sparked interest alone was not sufficient to consider engineering careers. Research on the sustained development of interest in engineering highlights rich networks of formal and informal experiences as catalysts or supportive infrastructure. Yet, access to such opportunities varies greatly. School systems often lack the necessary personnel, money, or space to offer these experiences, and, even if opportunities are available, often only a small subset of students may be able to participate. Further, common views of what engineering work is and who can do it are narrow, biased, and exclusive. This CAREER project has focused on three areas of research. The first area, focused on school-industry partnerships through COVID-19 in the region, highlighted the importance of rich partnerships, resilient stakeholders, and innovative contexts to persist throughout the COVID-19 pandemic. This is particularly pertinent to partnerships and collaboration, sustainability of these collaborations, and programming in the context of STEM skilled technical workforce development programs in rural places. The second area of research, focused on developing a conceptual framework for engineering education research and engagement in rural places, highlighted the importance of place, individual student and community assets, and leveraging these things to provide context and meaning in a decontextualized K-12 curriculum. Finally, the third research area, focused on systematically reviewing literature related to the assessment of systems thinking in K-12 education, highlighted the lack of comprehensive assessment tools that can apply across many educational disciplines but particularly in areas as it relates to socio-technical problems. Together, these three research areas ultimately seek to inform broader aspects of K-12 education, such as career and technical education, issues related to rural education, and ultimately focusing on students’ ability to handle complex problems in their communities or other contexts with systems thinking. 

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3. Board 272: Engineering Pathways for Appalachian Youth: Design Principles and Long-term Impacts of School-Industry Partnerships

   Schilling, M.R. ; Grohs, J.R. ( June 2023 , 2023 ASEE Annual Conference & Exposition)

   Broadening participation in the skilled technical workforce is a national priority given strong evidence of growing critical vacancies in engineering coupled with the urgent need for this workforce to better reflect the rich diversity of the nation. Scholars and activists often call for increased focus on education access, quality, and workforce development among rural Appalachian communities, noting that students from these communities are under-represented in higher education generally, and engineering careers specifically. Investing in preK-12 education, engaging youth as valued members of their communities, and cultivating workforce opportunities such as in advanced manufacturing have all been highlighted by the Appalachian Regional Commission as vital to strengthening economic resilience. However, scaffolding engineering and technical career pathways for Appalachian youth at scale in the context of broader systemic issues is challenging. Past research on the career choices of Appalachian youth show that sparked interest alone was not sufficient to consider engineering careers. Research on the sustained development of interest in engineering highlights rich networks of formal and informal experiences as catalysts or supportive infrastructure. Yet, access to such opportunities varies greatly. School systems often lack the necessary personnel, money, or space to offer these experiences, and, even if opportunities are available, often only a small subset of students may be able to participate. Further, common views of what engineering work is and who can do it are narrow, biased, and exclusive. This CAREER project has focused on three areas of research. The first area, focused on school-industry partnerships through COVID-19 in the region, highlighted the importance of rich partnerships, resilient stakeholders, and innovative contexts to persist throughout the COVID-19 pandemic. This is particularly pertinent to partnerships and collaboration, sustainability of these collaborations, and programming in the context of STEM skilled technical workforce development programs in rural places. The second area of research, focused on developing a conceptual framework for engineering education research and engagement in rural places, highlighted the importance of place, individual student and community assets, and leveraging these things to provide context and meaning in a decontextualized K-12 curriculum. Finally, the third research area, focused on systematically reviewing literature related to the assessment of systems thinking in K-12 education, highlighted the lack of comprehensive assessment tools that can apply across many educational disciplines but particularly in areas as it relates to socio-technical problems. Together, these three research areas ultimately seek to inform broader aspects of K-12 education, such as career and technical education, issues related to rural education, and ultimately focusing on students’ ability to handle complex problems in their communities or other contexts with systems thinking. 

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4. Work in Progress: Content Validation of an Engineering Process Safety Decision Making Instrument.

   Butler, B ; Anastasio, D ; Burkey, D ; Cooper, M ; Bodnar, C. ( January 2018 , ASEE Annual Conference proceedings)

   Process safety is at the heart of operation of many chemical processing companies. However, the Chemical Safety Board (CSB) has still documented over 800 investigations of process safety failures since the year 2000. While not all of these incidents were severe, some did lead to employee injuries or death and environmental harm. As a result, chemical engineering companies are increasingly dedicated to process safety through training programs and detailed vigilance as part of their operations practice. AIChE and OSHA also offer courses in process safety to help support the industry. These efforts illustrate the paramount importance that chemical engineering graduates have an appreciation and understanding of process safety as they transition from their degree program into industrial positions. Previous studies have shown that despite difficulties due to course load constraints, process safety has been incorporated into chemical engineering curriculum through either the addition of new courses, incorporation of the content within existing classes, or a combination of the two methods. A review performed in Process Safety Progress suggested that a key step for departments moving forward is to perform an assessment of the process safety culture within their institution in order to determine how faculty and students view process safety. An issue with completing this task is the lack of assessment tools that can be used to determine how students are developing their understanding of process safety decision making. This observation led to the development of the Engineering Process Safety Research Instrument (EPSRI). This instrument is modeled after the Defining Issues Test version 2 (DIT2) and the Engineering Ethical Reasoning Instrument (EERI). Similar to these instruments, the EPSRI provides dilemmas, three decisions, and 12 additional considerations that individuals must rate based on their relative importance to their decision making process. The dilemmas developed in the EPSRI are based on case studies and investigations from process safety failures that have occurred in industry to provide a realistic context for the decision making decisions that engineers may be faced with upon employment. The considerations provided after the scenario are derived to reflect pre-conventional, conventional, and post-conventional decision making thinking as described by Kohlberg’s Moral Development Theory. Pre-conventional decision making thinking focuses particularly on what is right/wrong or good/bad from an individual level, whereas post-conventional thinking seeks to determine what is correct from moral and value perspectives at the society level. This WIP paper describes the content validity study conducted while developing the EPSRI. Dilemmas were examined by context experts including professionals in the process industry, chemical engineering departments, and learning sciences field. Content experts reviewed the dilemmas and determined whether they represented accurate examples of process safety decision making that individuals may face in real-world engineering settings. The experts also reviewed the 12 considerations for each dilemma for their accuracy in capturing pre-conventional, conventional and post-conventional thinking. This work represents the first step in the overall instrument validation that will take place over the next academic year. 

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5. Work in Progress: Content Validation of an Engineering Process Safety Decision-making Instrument (EPSRI)

   Butler, B. L. ; Anastasio, D. D. ; Burkey, D. D. ; Cooper, M. ; Bodnar, C. A. ( June 2018 , ASEE annual conference & exposition proceedings)

   Process safety is at the heart of operation of many chemical processing companies. However, the Chemical Safety Board (CSB) has still documented over 800 investigations of process safety failures since the year 2000. While not all of these incidents were severe, some did lead to employee injuries or death and environmental harm. As a result, chemical engineering companies are increasingly dedicated to process safety through training programs and detailed vigilance as part of their operations practice. AIChE and OSHA also offer courses in process safety to help support the industry. These efforts illustrate the paramount importance that chemical engineering graduates have an appreciation and understanding of process safety as they transition from their degree program into industrial positions. Previous studies have shown that despite difficulties due to course load constraints, process safety has been incorporated into chemical engineering curriculum through either the addition of new courses, incorporation of the content within existing classes, or a combination of the two methods. A review performed in Process Safety Progress suggested that a key step for departments moving forward is to perform an assessment of the process safety culture within their institution in order to determine how faculty and students view process safety. An issue with completing this task is the lack of assessment tools that can be used to determine how students are developing their understanding of process safety decision making. This observation led to the development of the Engineering Process Safety Research Instrument (EPSRI). This instrument is modeled after the Defining Issues Test version 2 (DIT2) and the Engineering Ethical Reasoning Instrument (EERI). Similar to these instruments, the EPSRI provides dilemmas, three decisions, and 12 additional considerations that individuals must rate based on their relative importance to their decision making process. The dilemmas developed in the EPSRI are based on case studies and investigations from process safety failures that have occurred in industry to provide a realistic context for the decision making decisions that engineers may be faced with upon employment. The considerations provided after the scenario are derived to reflect pre-conventional, conventional, and post-conventional decision making thinking as described by Kohlberg’s Moral Development Theory. Pre-conventional decision making thinking focuses particularly on what is right/wrong or good/bad from an individual level, whereas post-conventional thinking seeks to determine what is correct from moral and value perspectives at the society level. This WIP paper describes the content validity study conducted while developing the EPSRI. Dilemmas were examined by context experts including professionals in the process industry, chemical engineering departments, and learning sciences field. Content experts reviewed the dilemmas and determined whether they represented accurate examples of process safety decision making that individuals may face in real-world engineering settings. The experts also reviewed the 12 considerations for each dilemma for their accuracy in capturing pre-conventional, conventional and post-conventional thinking. This work represents the first step in the overall instrument validation that will take place over the next academic year. 

   more » « less