STEM (science, technology, engineer, mathematics) education and engineering education are receiving an increasing amount of interest worldwide, but related research on the influence of STEM courses on students' engineering problem solving in China is scarce. Considering the rapid prototyping function of laser-cutting tools, this study was conducted to develop a STEM course based on laser cutting and to explore how the course affected high school students' engineering problem-solving abilities. A 9-week curriculum was implemented in a science, technology, and fabricating club of a high school in Zhejiang, China. The data were collected by pretest and posttest questionnaires and presentations of group assignments. The results were as follows. First, when presented with an engineering problem, the students demonstrated problem-solving abilities because they followed principles of engineering design, such as sketching, modeling and modifying. Second, while completing the assignment, the students proposed solutions with comprehensive factors in many aspects. They showed high-level thinking, such as consideration of the background, limiting conditions, and multidisciplinary knowledge, and they used technological tools to complete the task. However, some students ignored the assessment and redesign of their solutions. Further research could use a larger sample from different grades and explore how a STEM course combined with technology tools could influence students' high-level thinking skills.
Citation: Ruiheng Cai, Feng-kuang Chiang. A laser-cutting-centered STEM course for improving engineering problem-solving skills of high school students in China[J]. STEM Education, 2021, 1(3): 199-224. doi: 10.3934/steme.2021015
STEM (science, technology, engineer, mathematics) education and engineering education are receiving an increasing amount of interest worldwide, but related research on the influence of STEM courses on students' engineering problem solving in China is scarce. Considering the rapid prototyping function of laser-cutting tools, this study was conducted to develop a STEM course based on laser cutting and to explore how the course affected high school students' engineering problem-solving abilities. A 9-week curriculum was implemented in a science, technology, and fabricating club of a high school in Zhejiang, China. The data were collected by pretest and posttest questionnaires and presentations of group assignments. The results were as follows. First, when presented with an engineering problem, the students demonstrated problem-solving abilities because they followed principles of engineering design, such as sketching, modeling and modifying. Second, while completing the assignment, the students proposed solutions with comprehensive factors in many aspects. They showed high-level thinking, such as consideration of the background, limiting conditions, and multidisciplinary knowledge, and they used technological tools to complete the task. However, some students ignored the assessment and redesign of their solutions. Further research could use a larger sample from different grades and explore how a STEM course combined with technology tools could influence students' high-level thinking skills.
[1] | (2009) Engineering in K-12 education: Understanding the status and improving the prospects.National Academies Press. |
[2] | How an integrative STEM curriculum can benefit students in engineering design practices. International Journal of Technology and Design Education (2017) 27: 107-129. |
[3] | Learning from problems. The Science Teacher (2000) 67: 28. |
[4] | Božić, M. Č., Engineering practice: teaching ill-structured problem solving in an internship-like course, in IEEE Global Engineering Education Conference (EDUCON), 2014, pp. 721-726. |
[5] | Chinaos New Engineering Construction for the Future. Education Research, Tsinghua University (2017) 38: 26-35. |
[6] | An international comparative study on engineering talents training models. Research in Higher Education of Engineering (2011) 2: 33-41. |
[7] | (2013) Next generation science standards: For states, by states. |
[8] | (2015) STEM road map: A framework for integrated STEM education. |
[9] | Advancing integrated STEM learning through engineering design: Sixth-grade studentso design and construction of earthquake resistant buildings. The Journal of Educational Research (2017) 110: 255-271. |
[10] | The ITEEA 6E Learning ByDesign™ Model_ Maximizing Informed Design and Inquiry in the Integrative STEM Classroom. Technology & Engineering Teacher (2014) 73: 14-19. |
[11] | Engineering Design Thinking, Teaching, and Learning. Journal of Engineering Education (2005) 94: 103-120. |
[12] | The role of content knowledge in ill-structured problem solving for high school physics students. Research in Science Education (2018) 48: 165-179. |
[13] | Integrating STEM in an engineering design process: The learning experience of rural secondary school students in an outreach challenge program. Journal of Baltic Science Education (2016) 15: 477-493. |
[14] | STEM learning through engineering design: fourth-grade studentso investigations in aerospace. International Journal of STEM Education (2015) 2: 14. |
[15] | Engineering design in the primary school: Applying STEM concepts to build an optical instrument. International Journal of Science Education (2016) 38: 2762-2794. |
[16] | Engineering design thinking: High school studentso performance and knowledge. Journal of Engineering Education (2015) 104: 417-432. |
[17] | Kothiyal, A.R., Delayed Guidance: A teaching-learning strategy to develop ill-structured problem solving skills in engineering, in 2015 International Conference on Learning and Teaching in Computing and Engineering, 2015, pp. 164-171. |
[18] | An ill-structured PBL-based microprocessor course without formal laboratory. IEEE Transactions on Education (2011) 55: 145-153. |
[19] | Instructional design models for well-structured and III-structured problem-solving learning outcomes. Educational technology research and development (1997) 45: 65-94. |
[20] | What laser cutting technology brings to the creator education. Science and Technology Education in China (2017) 58-59. |
[21] | Creator Education: Origin, Intension and Possible Path. Comparative Education Research (2016) 1: 2-28. |
[22] | Study on the curriculum system of creator education based on the creator space--Taking the creator space of Northwestern University of Technology as an example. Modern Educational Technology (2017) 27: 109-14. |
[23] | (2016) An open source tool for science education 1-5. |
[24] | Gadjanski, I.R., Formation of Fab lab Petnica, in 2016 International Conference Multidisciplinary Engineering Design Optimization (MEDO), 2016, pp. 1-4. |
[25] | Laser Processing and 3D Printing Technology: Teaching Research for Engineering Thinking Training. Mechanical Design and Manufacturing Engineering (2017) 28. |
[26] | Practical Inquiry of Maker Education in Industrial Product Design Teaching. Art and Science Navigation (2017) 78. |
[27] | (2011) Second international handbook of science education.Springer Science & Business Media. |
[28] | Wilson, A.A., High school students' cognitive activity while solving authentic problems through engineering design processes, in Conference Proceedings of the American Society for Engineering Education. American Society of Engineering Education, 2013. |