Araştırma Makalesi
Yıl 2024,
Cilt: 39 Sayı: 1, 521 - 534, 21.08.2023
Öz
Kaynakça
- 1. Zhang J., Tang T.Q., Yan Y., Qu X., Eco-driving control for connected and automated electric vehicles at signalized intersections with wireless charging, Applied Energy, 282, 116215, 2021.
- 2. Zhang Y., Liu X., Wei W., Peng T., Hong G., Meng C., Mobile charging: a novel charging system for electric vehicles in urban areas, Applied Energy, 278, 115648, 2020.
- 3. Ding X., Du M., Duan C., Guo H., Xiong R., Xu J., Analytical and experimental evaluation of SiC-inverter nonlinearities for traction drives used in electric vehicles, IEEE Transactions on Vehicular Technology, 67(1),146–59, 2017.
- 4. Khoshvaght-Aliabadi M., Nozan F., Water cooled corrugated minichannel heat sink for electronic devices: Effect of corrugation shape, International Communications in Heat and Mass Transfer, 76:188–96, 2016.
- 5. Van Erp R., Kampitsis G., Matioli E., Efficient microchannel cooling of multiple power devices with compact flow distribution for high power-density converters. IEEE Transaction Power Electron, 35(7):7235–45, 2019.
- 6. Liang J., Xu H., Yuan Z., Zhou P., High efficiency liquid cooling system of power electronic converter, 5th Asia Conference on Power and Electrical Engineering, 1270-1275, 2020.
- 7. Sakanova A., Tong C.F., Nawawi A., Simanjorang R., Tseng K., Gupta A., Investigation on weight consideration of liquid coolant system for power electronics converter in future aircraft, Applied Thermal Engineering, 104, 603–615, 2016.
- 8. Micheli L., Reddy K.S., Mallick T.K., General correlations among geometry, orientation and thermal performance of natural convective micro-finned heat sinks, International Journal of Heat and Mass Transfer, 91, 711–724, 2015.
- 9. Cova P., Delmonte N., Chiozzi D., Portesine M., Vaccaro F., Mantegazza E., Water cold plates for high power converters: a software tool for easy optimized design, Microelectron Reliability, 88, 801–805, 2018.
- 10. Han F., Guo H., Ding X., Design and optimization of a liquid cooled heat sink for a motor inverter in electric vehicles, Applied Energy, 291,116819, 2021.
- 11. Sheng I.L.S., How K.B., Hoo T.E., Teaching, Learning & Applying TRIZ in University, The 11th International Matriz Conference TRIZ, 10-12 Eylül 2015.
- 12. Terninko J., Zusman A., Zlotin B., Systematic innovation: an introduction to TRIZ (theory of inventive problem solving), CRC press, ISBN 9781574441116, Published April 15, 1998.
- 13. Canbulut F., Demirtaş B., Using Brainstorming and TRIZ Together in Design/Improvement Process - Example of Baza Scissors System. Gazi University Journal of Science Part C: Design and Technology, 7 (3) , 614-626, 2019.
- 14. Canbulut F., Demirtaş B., Application of triz inventive principles to innovate the multi-tool drill machine, Journal of the Faculty of Engineering and Architecture of Gazi University, 37 (1) , 317-328, 2022.
- 15. Yang W., Cao G., Peng Q., Sun Y., Effective radical innovations using integrated QFD and TRIZ, Computers & Industrial Engineering,162, 107716, 2021.
- 16. Lin Y.S., Chen M., Implementing TRIZ with Supply Chain Management in New Product Development for Small and Medium Enterprises, Processes, 9, 614, 2021.
- 17. Spreafico C., Russo D., TRIZ Industrial Case Studies: A Critical Survey, Procedia CIRP, 39, 51–56, 2016.
- 18. Altshuller G., Creativity as an Exact Science, Translated by Anthony Williams. Gordon & Breach, NY, 1988.
- 19. Ko Y.T., Chen M.S., Yang C.C., Modelling a contradiction-oriented design approach for innovative product design, Proc IMechE, Part B: Journal of Engineering Manufacture, 299, 199–211, 2015.
- 20. Shulyak L., Three steps for solving an inventive problem, In: Altshuller G (eds) 40 principles: TRIZ keys to technical innovation (TRIZ tools, vol. 1, 1st ed.). Worcester, MA: Technical Innovation Center, Inc., pp.107–108, 2001.
- 21. The 40 TRIZ prenciples. http://www.triz40.com/aff_Principles_TRIZ.php. Erişim Tarihi Kasım 10, 2021.
- 22. Taguchi G., Introduction to quality engineering, Asian Productivity Organization, Tokyo, 1990.
Elektrikli araçlarda optimum soğutucu tasarımı için TRIZ algoritmasının uygulanması ve Taguchi analizi
Öz
Bu çalışma, elektrikli araçların soğutucu tasarımında TRIZ (İnovatif problem çözme teorisi) yönteminin sonuçları ne kadar artırdığının nicel bir değerlendirmesini sunmaktadır. Problem tanımlandıktan sonra TRIZ çelişkiler matrisi ile inovatif prensipler uygulanmıştır. Özellikle maliyetli çözüm olmaması için geometrik parametreler esas alınmıştır. Yenilikçi çözüm için kanal giriş uzunluğu, kanat sayısı ve kanat türü parametrelerinin soğutma ve basınç kaybı üzerindeki etkisi Taguchi analizinde incelenmiştir. Kanal içi akış problemi sonuçları Comsol programında nümerik olarak gerçekleştirilmiştir. Maksimum ısı yayılımı ve basınç kaybı için en etkili parametrenin kanat sayısı (%83,11-%87,27) olduğu görülmüştür. Isı yayılımı açısından TRIZ analizi ile sonuç tasarımında, mevcut durumuna göre %6,6, basınç kaybı açısından %14,14 iyileşme gerçekleşmiştir. Ayrıca doğrulama çalışması için simülasyon ile Taguchi analizi sonuçları karşılaştırılmıştır. Sonuçların birbirine yakın olduğu tespit edilmiştir.
Anahtar Kelimeler
Elektrikli araçlar Sıvı soğutma Soğutucu TRIZ inovasyon Taguchi
Kaynakça
- 1. Zhang J., Tang T.Q., Yan Y., Qu X., Eco-driving control for connected and automated electric vehicles at signalized intersections with wireless charging, Applied Energy, 282, 116215, 2021.
- 2. Zhang Y., Liu X., Wei W., Peng T., Hong G., Meng C., Mobile charging: a novel charging system for electric vehicles in urban areas, Applied Energy, 278, 115648, 2020.
- 3. Ding X., Du M., Duan C., Guo H., Xiong R., Xu J., Analytical and experimental evaluation of SiC-inverter nonlinearities for traction drives used in electric vehicles, IEEE Transactions on Vehicular Technology, 67(1),146–59, 2017.
- 4. Khoshvaght-Aliabadi M., Nozan F., Water cooled corrugated minichannel heat sink for electronic devices: Effect of corrugation shape, International Communications in Heat and Mass Transfer, 76:188–96, 2016.
- 5. Van Erp R., Kampitsis G., Matioli E., Efficient microchannel cooling of multiple power devices with compact flow distribution for high power-density converters. IEEE Transaction Power Electron, 35(7):7235–45, 2019.
- 6. Liang J., Xu H., Yuan Z., Zhou P., High efficiency liquid cooling system of power electronic converter, 5th Asia Conference on Power and Electrical Engineering, 1270-1275, 2020.
- 7. Sakanova A., Tong C.F., Nawawi A., Simanjorang R., Tseng K., Gupta A., Investigation on weight consideration of liquid coolant system for power electronics converter in future aircraft, Applied Thermal Engineering, 104, 603–615, 2016.
- 8. Micheli L., Reddy K.S., Mallick T.K., General correlations among geometry, orientation and thermal performance of natural convective micro-finned heat sinks, International Journal of Heat and Mass Transfer, 91, 711–724, 2015.
- 9. Cova P., Delmonte N., Chiozzi D., Portesine M., Vaccaro F., Mantegazza E., Water cold plates for high power converters: a software tool for easy optimized design, Microelectron Reliability, 88, 801–805, 2018.
- 10. Han F., Guo H., Ding X., Design and optimization of a liquid cooled heat sink for a motor inverter in electric vehicles, Applied Energy, 291,116819, 2021.
- 11. Sheng I.L.S., How K.B., Hoo T.E., Teaching, Learning & Applying TRIZ in University, The 11th International Matriz Conference TRIZ, 10-12 Eylül 2015.
- 12. Terninko J., Zusman A., Zlotin B., Systematic innovation: an introduction to TRIZ (theory of inventive problem solving), CRC press, ISBN 9781574441116, Published April 15, 1998.
- 13. Canbulut F., Demirtaş B., Using Brainstorming and TRIZ Together in Design/Improvement Process - Example of Baza Scissors System. Gazi University Journal of Science Part C: Design and Technology, 7 (3) , 614-626, 2019.
- 14. Canbulut F., Demirtaş B., Application of triz inventive principles to innovate the multi-tool drill machine, Journal of the Faculty of Engineering and Architecture of Gazi University, 37 (1) , 317-328, 2022.
- 15. Yang W., Cao G., Peng Q., Sun Y., Effective radical innovations using integrated QFD and TRIZ, Computers & Industrial Engineering,162, 107716, 2021.
- 16. Lin Y.S., Chen M., Implementing TRIZ with Supply Chain Management in New Product Development for Small and Medium Enterprises, Processes, 9, 614, 2021.
- 17. Spreafico C., Russo D., TRIZ Industrial Case Studies: A Critical Survey, Procedia CIRP, 39, 51–56, 2016.
- 18. Altshuller G., Creativity as an Exact Science, Translated by Anthony Williams. Gordon & Breach, NY, 1988.
- 19. Ko Y.T., Chen M.S., Yang C.C., Modelling a contradiction-oriented design approach for innovative product design, Proc IMechE, Part B: Journal of Engineering Manufacture, 299, 199–211, 2015.
- 20. Shulyak L., Three steps for solving an inventive problem, In: Altshuller G (eds) 40 principles: TRIZ keys to technical innovation (TRIZ tools, vol. 1, 1st ed.). Worcester, MA: Technical Innovation Center, Inc., pp.107–108, 2001.
- 21. The 40 TRIZ prenciples. http://www.triz40.com/aff_Principles_TRIZ.php. Erişim Tarihi Kasım 10, 2021.
- 22. Taguchi G., Introduction to quality engineering, Asian Productivity Organization, Tokyo, 1990.
Toplam 22 adet kaynakça vardır.
Ayrıntılar
| Birincil Dil | Türkçe |
|---|---|
| Konular | Mühendislik |
| Bölüm | Makaleler |
| Yazarlar | |
| Erken Görünüm Tarihi | 11 Ağustos 2023 |
| Yayımlanma Tarihi | 21 Ağustos 2023 |
| Gönderilme Tarihi | 12 Şubat 2022 |
| Kabul Tarihi | 19 Mart 2023 |
| Yayımlandığı Sayı | Yıl 2024 Cilt: 39 Sayı: 1 |