Journal of Applied Engineering Science
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2018, vol. 16, br. 3, str. 374-382
Comprehensive integration as an effective way of training future designers at technical universities (Integration as a way of training a designer)
(naslov ne postoji na srpskom)
Nosov Magnitogorsk State Technical University, Magnitogorsk, Russia

Ključne reči: Comprehensive integration; Professional training of the designer; Intersubject links; Designer's personal qualities; Integration model; Activity; Designing
(ne postoji na srpskom)
The article deals with the possibilities of comprehensive integration as a way to upgrade the professional training of designers. The authors see a means of resolving some problems of design education in it. To realize this goal, a prognostic model was developed, linking all the components: the content, methodology of the teacher's work, and student activities. This model was built on the basis of data obtained in the process of studying the activities of design practitioners, for which a survey was carried out and an interview was held with each of them. Particular attention was paid to the difficulties experienced by young designers in the first years of their work, as well as experienced professionals, watching their young colleagues' activities. The authors propose to use both 'vertical' and 'horizontal' integration in the learning process, since each has its own advantages. In this case, the formation of future designers' necessary competences is completely ensured, which should be manifested in a holistic and flexible thinking capable of solving design problems of any complexity level. To check the availability of such thinking, a special task was developed in the field of environmental design. Students designed the product from construction waste, thereby solving the actual problem of recycling and reuse of old materials. The purpose of this article is the authors' desire to share their accumulated work experience, to give the pedagogical community the opportunity to discuss the results obtained for the further implementation of the integrative approach in the professional training of future designers.
Afdal, H.W., Spernes, K. (2018) Designing and redesigning research-based teacher education. Teaching and Teacher Education, 74: 215-228
Antonova, N.N. (2005) From the history of development of professional design education in Russia. Scientific Information Bulletin of Doctoral Students, Post-Graduates, Students, vol. 2, no. 6, 200-205
Aristova, U.V. (2007) Modeling of system of designers' professional training in high school. Moscow: Open Social University, Moscow
Arnesson, K., Albinsson, G. (2012) Integration of theory and practice in higher education. International Journal of Educational Research, 53: 370-380
Babikova, V.V., Sokolov, M.V. (2017) Approaches to the development of creativity in design. Current Trends in Fine. Decorative and Applied Art and Design, no. 2, 170-175
Banduristy, F.F. (2001) Optimization of teaching artistic design in the system of special training of the teacher of fine art in pedagogical educational establishments (universities). Moscow: Prometheus
Barlex, D., Pitt, J. (1999) Technological education in schools of Great Britain. School and Production, no. 5, 93-95
Bauhaus-Chronik, B.M. (1952) Vom Bauhaus in Weimar zur Hochschule für Gestaltung in Ulm. Deutsche Universitätszeitung, no. 23-24
Benson, E., Fine, P. (2011) Sustainable Design Education Rethought: The Case for Eco-modernism. Design Principles and Practices: An International Journal-Annual Review, 4(6): 163-176
Bezrukova, V.S. (1994) Integration processes in pedagogical theory and practice. Ekaterinburg: Russian State Vocational Pedagogical University
Boks, C. (2006) The soft side of ecodesign. Journal of Cleaner Production, 14(15-16): 1346-1356
Brunsgaard, C., Dvořáková, P., Wyckmans, A., Stutterecker, W., Laskari, M., Almeida, M., Kabele, K., Magyar, Z., Bartkiewicz, P., Op, `t V.P. (2014) Integrated energy design - Education and training in cross-disciplinary teams implementing energy performance of buildings directive (EPBD). Building and Environment, 72: 1-14
Chandrasegaran, S., Badam, S.K., Kisselburgh, L., Peppler, K., Elmqvist, N., Ramani, K. (2017) VizScribe: A visual analytics approach to understand designer behavior. International Journal of Human-Computer Studies, 100: 66-80
Donnelly, K., Beckett-Furnell, Z., Traeger, S., Okrasinski, T., Holman, S. (2006) Eco-design implemented through a product-based environmental management system. Journal of Cleaner Production, 14(15-16): 1357-1367
Druzhkova, N.I. (2012) The Ulm Higher School of Design (1953-1968). Pedagogy of Art, no.2, from http://www.art-education.ru/sites/default/files/journal_ pdf/drugkova_12_june.pdf, accessed on 2017-09-29
Fakhrutdinova, R.A., Akhmetova, G.P. (2014) Developing professional competence of students, future designers, in higher education training. Philology and Culture, vol. 2, no. 36, 298-301
Figueiró, P.S., Raufflet, E. (2015) Sustainability in higher education: a systematic review with focus on management education. Journal of Cleaner Production, 106: 22-33
Flaig, M., Simonsmeier, B.A., Mayer, A., Rosman, T., Gorges, J., Schneider, M. (2018) Conceptual change and knowledge integration as learning processes in higher education: A latent transition analysis. Learning and Individual Differences, 62: 49-61
Gantogtokh, O., Quinlan, K.M. (2017) Challenges of designing interdisciplinary postgraduate curricula: case studies of interdisciplinary master’s programmes at a research-intensive UK university. Teaching in Higher Education, 22(5): 569-586
Grajewski, D., Diakun, J., Wichniarek, R., Dostatni, E., Buń, P., Górski, F., Karwasz, A. (2015) Improving the Skills and Knowledge of Future Designers in the Field of Ecodesign Using Virtual Reality Technologies. Procedia Computer Science, 75: 348-358
Gropius, W. (1923) Idee und Aufbau des Staatlichen Bauhauses. Weimar: Münch
Hotaling, L., Sheryll, R., Sheppard, K., Chassapis, C., Mcgrath, E. (2007) A paradigm for vertically integrated curriculum innovation: How curricula were developed for undergraduate, middle and high school students using underwater robotics. u: International Conference on Engineering Education - ICEE, from http://ciese.org/papers/2007/icee2007_LEGO_finalpaper.pdf, accessed on 2018-07-01
Ismail, M.A., Keumala, N., Dabdoob, R.M. (2017) Review on integrating sustainability knowledge into architectural education: Practice in the UK and the USA. Journal of Cleaner Production, 140: 1542-1552
Jansen, A., Stevels, A. (2006) Combining eco-design and user benefits from human-powered energy systems, a win-win situation. Journal of Cleaner Production, 14(15-16): 1299-1306
Johansson, G., Magnusson, T. (2006) Organising for environmental considerations in complex product development projects: implications from introducing a “Green” sub-project. Journal of Cleaner Production, 14(15-16): 1368-1376
Karakaya, A.F., Demirkan, H. (2015) Collaborative digital environments to enhance the creativity of designers. Computers in Human Behavior, 42: 176-186
Karlsson, R., Luttropp, C. (2006) EcoDesign: what's happening? An overview of the subject area of EcoDesign and of the papers in this special issue. Journal of Cleaner Production, 14(15-16): 1291-1298
Kentgens-Craig, M., Dessau, S.B. (1999) The Dessau Bauhaus building. Basel-Berlin-Boston: Birkhäuser
Klaassen, R.G. (2018) Interdisciplinary education: a case study. European Journal of Engineering Education, 43(6): 842-859
Klement, M. (2017) Models of integration of virtualization in education: Virtualization technology and possibilities of its use in education. Computers & Education, 105: 31-43
Kondratieva, K.A. (2005) Some conceptual foundations of design education: Stroganov Moscow State Academy of Design and Applied Arts. Moscow: Moscow State Stroganov University of Design and Applied Arts
Ladygin, E.V. (2000) Development of students' creative abilities in the integrative active learning at the course 'Fundamentals of Design'. Moscow
Lambrechts, W., Mulà, I., Ceulemans, K., Molderez, I., Gaeremynck, V. (2013) The integration of competences for sustainable development in higher education: an analysis of bachelor programs in management. Journal of Cleaner Production, 48: 65-73
Leal, F.W., Shiel, C., Paço, A. (2016) Implementing and operationalising integrative approaches to sustainability in higher education: the role of project-oriented learning. Journal of Cleaner Production, 133: 126-135
Lilley, D., Lofthouse, V. (2009) Sustainable design education - considering design for behavioural change. Engineering Education, 4(1): 29-41
Lofthouse, V. (2006) Ecodesign tools for designers: defining the requirements. Journal of Cleaner Production, 14(15-16): 1386-1395
Perdan, S., Azapagic, A., Clift, R. (2000) Teaching sustainable development to engineering students. International Journal of Sustainability in Higher Education, 1(3): 267-279
Popugaeva,, Ya, I., Ryazanov, V.N., Dolikhin, T.A. (2007) On pre-profile training on the basis of the institution of additional education of children. Education of Schoolchildren, no. 10, 40-44
Richter, D.M., Paretti, M.C. (2009) Identifying barriers to and outcomes of interdisciplinarity in the engineering classroom. European Journal of Engineering Education, 34(1): 29-45
Schuster, L., Glavas, C. (2017) Exploring the dimensions of electronic work integrated learning (eWIL). Educational Research Review, 21: 55-66
Sirotina, I.L., Schekochikhina, O.D. (2016) Digital arts as a factor in the optimization of professional development of a designer. u: The International Scientific and Practical Conference “Russian Creative Education in the Field of Digital Art in Accordance with EU Standards”, Proceedings of, p. 233-242
Stroganov Moscow State University of Arts and Industry-Moscow School of Design (1991) The experience of training specialists in MHPU. Moscow
Tangwanichagapong, S., Nitivattananon, V., Mohanty, B., Visvanathan, C. (2017) Greening of a campus through waste management initiatives. International Journal of Sustainability in Higher Education, 18(2): 203-217
Tarasova, O.P., Yanysheva, M.M. (2014) Formation of professional competencies of the future designer in educational and professional activity. Bulletin of the Orenburg State University, vol. 5, no. 166, 210-215
Thomas, H. (2018) Powerful knowledge, technology and education in the future-focused good society. Technology in Society, 52: 54-59
Tkachenko, E.V., Kozhukhovskaya, S.M. (2007) Design education in Russia. The world of education - education in the world. Interindustry Information Service, no. 1(25), 156-164
Tukhbatullina, L.M., Safina, L.A. (2013) Foreign experience in the application of project-based learning in polymer specialists' training. Bulletin of the Kazan Polytechnic University, no. 3, 333-335
Ueda, E.S. (2018) Student team integrating aspects of sustainability in practical design education. International Journal of Sustainability in Higher Education, 19(5): 877-892
Uncles, M.D. (2018) Directions in higher education: A marketing perspective. Australasian Marketing Journal (AMJ), 26(2): 187-193
van Nes, N., Cramer, J. (2006) Product lifetime optimization: a challenging strategy towards more sustainable consumption patterns. Journal of Cleaner Production, 14(15-16): 1307-1318
Vezzoli, C., Sciama, D. (2006) Life Cycle Design: from general methods to product type specific guidelines and checklists: a method adopted to develop a set of guidelines/checklist handbook for the eco-efficient design of NECTA vending machines. Journal of Cleaner Production, 14(15-16): 1319-1325
Wächter, C. (2012) Interdisciplinary Teaching and Learning for Diverse and Sustainable Engineering Education. u: Béraud, André; Godfroy, Anne-Sophie; Michel, Jean [ur.] GIEE 2011: Gender and Interdisciplinary Education for Engineers, Rotterdam: Springer Nature, str. 47-63
Walker, C., Gleaves, A. (2016) Constructing the caring higher education teacher: A theoretical framework. Teaching and Teacher Education, 54: 65-76
Yakovlev, I.P. (1987) Integration of the higher school with science and production. Leningrad: State University Publishing House
Zhdanova, N.S. (2010) Methods of teaching design in secondary school. Magnitogorsk: Magnitogorsk State University
Zhdanova, N.S., Zhdanov, A.A., i dr. (2015) Design product projecting made of recycled materials. International Journal of Applied Engineering Research, vol. 10, no. 24, 45137-45141
Zhdanova, N.S. (2007) Modeling the content of professional training for future designers. Bulletin of the Orenburg State University, vol. 11-2, no. 76, 52-57
Zwolinski, P., Lopez-Ontiveros, M., Brissaud, D. (2006) Integrated design of remanufacturable products based on product profiles. Journal of Cleaner Production, 14(15-16): 1333-1345

O članku

jezik rada: engleski
vrsta rada: izvorni naučni članak
DOI: 10.5937/jaes16-18279
objavljen u SCIndeksu: 04.10.2018.
metod recenzije: dvostruko anoniman
Creative Commons License 4.0

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