How to search?
advanced search

Search results

Filters

  • Journals
  • Autorzy
  • Słowa kluczowe
  • Data
  • Typ

Search results

Number of results: 3
items per page: 25 50 75
Sort by:

Concepts of energy use of municipal solid waste

Arkadiusz Primus Tadeusz Chmielniak Czesława Rosik-Dulewska
Archives of Environmental Protection | 2021 | vol. 47 | No 2 | 70-80 | DOI: 10.24425/aep.2021.137279
Keywords municipal solid waste hydrogen fuel cells cogeneration waste gasification
Download PDF Download RIS Download Bibtex

Abstract

The introduction highlights the technologies of converting the chemical energy of biomass and municipal waste into various forms of final energy (electricity, heat, cooling, new fuels) as important in the pursuit of a low-carbon economy, especially for energy and transport sector. The work continues to focus mainly on gasification as a process of energy valorization of the initial form of biomass or waste, which does not imply that other methods of biomass energy use are not considered or used. Furthermore, the article presents a general technological flowchart of gasification with a gas purification process developed by Investeko S.A. in the framework of Lifecogeneration.pl. In addition, selected properties of the municipal waste residual fraction are described, which are of key importance when selecting the technology for its energy recovery. Significant quality parameters were identified, which have a significant impact on the production and quality of syngas, hydrogen production and electricity generation capacity in SOFC cells. On the basis of the research on the waste stream, a preliminary qualitative assessment was made in the context of the possibility of using the waste gasification technology, syngas production with a significant share of hydrogen and in combination with the technology of energy production in oxide-ceramic SOFC cells. The article presents configurations of energy systems with a fuel cell, with particular emphasis on oxide fuel cells and their integration with waste gasification process. An important part of the content of the article is also the environmental protection requirements for the proposed solution.
Go to article

Bibliography

  1. Al-attab, K.A. & Zainal, Z.A. (2015). Externally fired gas turbine technology: A review. Applied Energy, 138, pp. 474–487, DOI: 10.1016/j.apenergy.2014.10.049
  2. Andersson, M., Yuan, J. & Sunden, B. (2010). Review on modeling development for multiscale chemical reactions coupled transport phenomena in solid oxide fuel cells. Applied Energy 87, pp. 1461–1476, DOI: 10.1016/j.apenergy.2009.11.013
  3. Regise, A., Muller, C., Schmid, M, Colomar, D., Ortloff, F., Sporl, R., Brisse, A. & Graf, F. (2019). Innovative power-to-gas plant concepts for upgrading of gasification bio-syngas through steam electrolysis and catalytic methanation. Energy Conversion and Management, 183, pp. 462–473. DOI: 10.1016/j.enconman.2018.12.101
  4. Bartela, Ł., Kotowicz, J. & Dubiel-Jurga, K. (2018). Investment risk for biomass integrated gasification combined heat and power unit with an internal combustion engine and a Stirling engine. Energy, 150, pp. 601 – 616. DOI: 10.1016/j.energy.2018.02.152
  5. Chmielniak, T. (2020). Energetyka wodorowa, s.378. PWN, Warszawa.
  6. Colpan, C. O., Hamdullahpur, F., Dincer, I. & Yoo, Y. (2010). Effect of gasification agent on the performance of solid oxide fuel cell and biomass gasification systems. I. J. of Hydrogen Energy, 35, pp. 5001 – 5009. DOI: 10.1016/j.ijhydene.2009.08.083
  7. Colpan , C.O. (2009). Thermal Modeling of Solid Oxide Fuel Cell Based Biomass Gasification Systems, Department of Mechanical and Aerospace Engineering Carleton University Ottawa, Ontario, Canada, (Thesis).
  8. Di Carlo, A., Borello, A. & Bocci, E. (2013). Process simulation of a hybrid SOFC/mGT and enriched air/steam fluidized bed gasifier power plant, I.J.of Hydrogen Energy, 38, pp. 5857-5874. DOI: 10.1016/j.ijhydene.2013.03.005
  9. Dong, L., Liu, H. & Riffat, S. (2009). Development of small-scale and micro-scale biomass fuelled CHP systems—a literature review. Appl Therm Eng, 29, pp.2119–26. DOI: 10.1016/j.applthermaleng.2008.12.004
  10. Integrated Emission Directive no. 2010/75/UE 24.11.2010.
  11. Fortunato B., Camporeale, S.M., Torresi, M. & Fornarelli, F. (2016). A Combined Power Plant Fueled by Syngas Produced in a Downdraft Gasifier, Proceedings of ASME Turbo Expo, GT2016-58159, V003T06A023. DOI: 10.1115/GT2016-58159
  12. Fryda, L., Panopoulos, K.D. & Kakaras, E. (2008). Integrated CHP with autothermal biomass gasification and SOFC–MGT. Energy Conversion and Management, 49, pp. 281–290. DOI: 10.1016/j.enconman.2007.06.013
  13. Götz, M., Lefebvre, J., Mörs, F., McDaniel Koch, A., Graf , F., Bajohr, S., Reimert,R. & Kolb, T., (2016). Renewable Power-to-Gas: A technological and economic review. Renewable Energy, 85, pp. 1371 – 1390. DOI: 10.1016/j.renene.2015.07.066
  14. Huang, Y., Wang, Y.D., Rezvani, S., McIlveen-Wright, D.R., Anderson, M., Mondol, J., Zacharopolous, A. & Hewitt, N. J. (2013). A techno-economic assessment of biomass fuelled trigeneration system integrated with organic Rankine cycle. Applied Thermal Engineering, 53, pp. 325 – 331. DOI: 10.1016/j.applthermaleng.2012.03.041
  15. Kupecki, J. (2018). Modelling, Design, Construction, and Operation of Power Generators with Solid Oxide Fuel Cells, s. 261. Springer.
  16. Kupecki, J. (2018). Selected problems of mathematical modeling of solid oxide fuel cell stacks during transient operation, p. 133. Wyd. Instytutu Technologii Eksploatacji, (in Polish)
  17. Kupecki, J., Skrzypkiewicz, M., Wierzbicki, M. & Stepien M. (2017). Experimental and numerical analysis of a serial connection of two SOFC stacks in a micro-CHP system fed by biogas. I.J. of Hydrogen Energy, 4, 2, pp. 3487 – 3497. DOI: 10.1016/j.ijhydene.2016.07.222
  18. Lian, Z.T., Chua, K.J. & Chou, S.K. (2010) A thermoeconomic analysis of biomass energy for trigeneration. Applied Energy, 87, pp. 84–95. DOI: 10.1016/j.apenergy.2009.07.003
  19. Maraver, D., Sin, A., Royo, J. & Sebastián, F. (2013). Assessment of CCHP systems based on biomass combustion for small-scale applications through a review of the technology and analysis of energy efficiency parameters. Applied Energy, 102, pp. 1303–1313. DOI: 10.1016/j.apenergy.2012.07.012
  20. Mathiesen, B.V., Lund, H., Connolly, D., Wenzel, H., Ostergaard, P.A., Moller, B., Nielsen, S., Ridjan, I., Karnoe, P., Sperling, K. & Hvelplund, F.K. (2015). Smart Energy Systems for coherent 100% renewable energy and transport solutions. Applied Energy, 145, pp. 139–154. DOI: 10.1016/j.apenergy.2015.01.075
  21. Mauro, A., Arpina, F., Massarotti, N. (2011). Three – dimensional simulation of heat and mass transport phenomena in planar SOFCs. I. J. of Hydrogen Energy, 36, pp. 10288 – 10301. DOI: 10.1016/j.ijhydene.2010.10.023
  22. Menon, V., Janardhanan, V.M., Tisher, S. & Deutschmann, O. (2012). A novel approach to model the transient behaviour of solid - oxide fuel cell stacks. J. of Power Sources, 214 pp. 227 – 238. DOI: 10.1016/j.jpowsour.2012.03.114
  23. Primus, A. & Rosik-Dulewska, C. (2018). Fuel potential of the over-sieve fraction of municipal waste and its role in the national model of waste management. Zeszyty Naukowe Instytutu Gospodarki Surowcami Mineralnymi i Energią PAN, 105, pp.121-134. DOI:10.24425/124382 (in Polish)
  24. Primus, A. & Rosik-Dulewska, C. (2019). Integration of energy and material recovery processes of municipal plastic waste into the national waste management system. Polityka Energetyczna Energy Policy Journal, 22, 4, pp. 129–140. DOI: 10.33223/epj/114741
  25. Puig-Arnavat, M, Bruno, J.C. & Coronas, A. (2014). Modeling of trigeneration configurations based on biomass gasification and comparison of performance. Applied Energ,y 114 pp. 845–856. DOI:10.1016/j.apenergy.2013.09.013
  26. Kempegowda, R.S., Assabumrungrat, S. & Laosiripojana, N. (2009). Integrated CHP System Efficiency Analysis of Air, Mixed Air- Steam And Steam Blown Biomass Gasification Fuelled SOFC, Proc.of the IASIED International Conf. Modelling, Simulation, and Indentification. October 12 -14, 2009, Beijing, China
  27. Nikdalila, R., Azad, |A.T., Saghir, M., Taweekun, J., Bakar, M.S.A., Reza, M.S. & Azad, A.K. (2020). A review on biomass derived syngas for SOFC based combined heat and power application. Renewable and Sustainable Energy Reviews, 119, 109560. DOI: 10.1016/j.rser.2019.109560
  28. Rasmussen, J.F.B. & Hagen, A. (2011). The effect of H2S on the performance of SOFCs using methane containing fuel. Fuel Cell, 10, pp. 1135 – 1142. HAL Id: hal-00576976
  29. Salehi A., Mousavi, S.M., Fasihfar, A. & Ravanbakhsh, M. (2019). Energy, exergy, and environmental (3E) assessments of an integrated molten carbonate fuel cell (MCFC), Stirling engine and organic Rankine cycle (ORC) cogeneration system fed by a biomass-fueled gasifier. I. J. of Hydrogen Energy, 44, pp. 31488-31505. DOI: 10.1016/j.ijhydene.2019.10.038
  30. Skorek J. & Kalina J. (2005). Gas cogeneration systems; Wydawnictwo Naukowo-Techniczne; Warszawa, 2005 r. (in Polish)
  31. Sipilä, K., Pursiheimo, E., Savola, T., Fogelholm, C.J., Keppo, I. & Pekka A. (2005). Small Scale Biomass CHP Plant and District Heating. Vtt Tiedotteita . Research Notes 2301, Valopaino Oy, Helsinki, 2005. http://www.vtt.fi/inf/pdf/tiedotteet/2005/T2301.pdf
  32. Ściążko, M. & Nowak, W. (2017). Municipal waste gasification technologies. Nowa Energia 1. technologie_zgazowania_odpadow_komunalnych_1.pdf (cire.pl)
  33. Thilak, N., Iniyan, R.S. & Goic, R. (2011). A review of renewable energy based cogeneration technologies. Renewable and Sustainable Energy Reviews, 15, pp. 3640–3648. DOI: 10.1016/j.rser.2011.06.003
  34. Uebbinga, M., Liisa, M., Rihko-Struckmanna, K. & Sundmachera, K. (2019). Exergetic assessment of CO2 methanation processes for the chemical storage of renewable energies. Applied Energy, 233–234, pp. 271–282. DOI: 10.1016/j.apenergy.2018.10.014
  35. Wielgosiński, G. (2020). Thermal waste conversion, Nowa Energia; Racibórz 2020 r. (in Polish)
  36. Wongchanapai, S., Iwai, H., Saito, M. & Yoshida, H. (2012). Performance evaluation of an integrated small-scale SOFC-biomass gasification power generation system. Journal of Power Sources, 216, pp. 314 – 322. DOI: 10.1016/j.jpowsour.2012.05.098
  37. Zhang W., Croiset, E., Douglas, P.L., Fowler, M.W & Entchev, E. (2005). Simulation of a tubular solid oxide fuel cells stack using Aspen PlusTM unit operation models. Energy Conversion and Management, 46, pp. 181 – 196. DOI: 10.1016/j.enconman.2004.03.002
Go to article

Authors and Affiliations

Arkadiusz Primus
1
Tadeusz Chmielniak
2
Czesława Rosik-Dulewska
3
ORCID: ORCID
  1. INVESTEKO S.A.
  2. Silesian University of Technology, Faculty of Energy and Environmental Engineering, Institute of Power Engineering and Turbomachinery, Poland
  3. Institute of Environmental Engineering, Polish Academy of Sciences, Poland

Tax audit in innovative development of the energy sector of the economy: Gobal trends

Lyazzat Sembiyeva Madina Serikova Katira Satymbekova Zhanat Tulegenova Begzat Nurmaganbetova Aida Zhagyparova
Journal of Water and Land Development | 2021 | No 48 | 70-80 | DOI: 10.24425/jwld.2021.136148
Keywords fuel energy innovative development institutional features integration process state tax audit tax administration
Download PDF Download RIS Download Bibtex

Abstract

As part of the study, world fuel and energy were analysed. A model for the development of state tax audit in the framework of innovative economic development is proposed. As a methodological base, general scientific research methods were used, first of all, systems and integrated analysis methods to substantiate the essence of the state tax audit, to develop approaches to the analysis of its results, and also to determine development trends. The importance of modernizing the system based on the identified relationship between the level of innovative development and the volume of tax revenues is substantiated. The developed model is based on the assumption that the tax gap will be minimized by encouraging tax-payers to voluntarily fulfil their tax obligations. The necessity of creating a supranational body of state audit within the framework of integration processes is substantiated. The prospects for the development of Supreme Audit Institutions (SAIs) in the context of globalization have been outlined, including the creation of territorial standards for a state audit of the Eurasian Economic Union (EAEU) countries.
Go to article

Bibliography

AKHMADEEV R.G., MOROZOVA T.V., VORONKOVA O., SITNOV A.A. 2019. Targets determination model for VAT risks mit-igation at B2B marketplaces. Entrepreneurship and Sustainability Issues. Vol. 7(2) p. 1197–1216. DOI 10.9770/jesi 2019.7.2(28).
AKHMETSHIN E.M., PLASKOVA N.S., IUSUPOVA I.I., PRODANOVA N.A., LEONTYEV A.N., VASILEV V.L. 2019. Dataset for determining rational taxation value with incompatible criteria of economic efficiency and equity. Data in Brief. Vol. 26, 104532. DOI 10.1016/j.dib.2019.104532.
ALLEN D.W., BERG C., LANE A.M., POTTS J. 2018. Cryptodemocracy and its institutional possibilities. The Review of Austrian Economics. Vol. 33 p. 363–374. DOI 10.1007/ s11138-018-0423-6
BEKKERS V., TUMMERS L. 2018. Innovation in the public sector: Towards an open and collaborative approach. International Review of Administrative Sciences. Vol. 84 (2) p. 209–213. DOI 10.1177/0020852318761797.
BROWN A., FISHENDEN J., THOMPSON M., VENTERS W. 2017. Appraising the impact and role of platform models and Government as a Platform (GaaP) in UK Government public service reform: Towards a Platform Assessment Framework (PAF). Government Information Quarterly. Vol. 34 (2) p. 167–182. DOI 10.1016/j.giq.2017.03.003.
CARTON F., BREZILLON P., FELLER J. 2016. Digital selves and decision-making contexts: towards a research agenda. Journal of Decision Systems. Vol. 25. Supl. 1 p. 96–105. DOI 10.1080/12460125.2016.1187416.
Deloitte 2017. Artificial intelligence enterning the world of tax [online]. Partner, Tax & Legal Deloitte. [Access 15.03.2020]. Available at: https://www2.deloitte.com/content/dam/Deloitte/global/Documents/Tax/dttl-tax-artificial-intelligence-in-tax.pdf
DUTTA S., LANVIN B., WUNSCH-VINCENT S. (eds.) 2019. Global innovation index 2019. Creating healthy lives – The future of medical innovation [online]. Ithaca, Fontainebleau, and Geneva. Cornell University, INSEAD, World Intellectual Property Organization. [Access 15.03.2020]. Available at: https://www.wipo.int/edocs/pubdocs/en/wipo_pub_gii_2019.pdf
DUTTON W.H., REISDORF B., DUBOIS E., BLANK G. 2017. Social shaping of the politics of internet search and networking: moving beyond filter bubbles, echo chambers, and fake news. Quello Center Working Paper. No. 2944191 p. 1–26. DOI 10.2139/ssrn.2944191.
HALE S.A., JOHN P., MARGETTS H., YASSERI T. 2018. How digital design shapes political participation: A natural experiment with social information. PloS One. Vol. 13(4), e0196068. DOI 10.1371/journal.pone.0196068.
KORABLEVA O.N., MITYAKOVA V.N., KALIMULLINA O.V. (2020). Designing a decision support system for predicting innovation activity. ICEIS 2020 – Proceedings of the 22nd International Conference on Enterprise Information Systems. Vol. 1 p. 619–625. DOI 10.5220/0009565706190625.
KORSAKOVA T.V., TIKHONOVSKOVA S.A., BAT N.M., SAENKO N.R., IGNATYEVA O.V., RIZVANOVA M.A. 2017. Career management of personnel in commercial enterprise. International Journal of Applied Business and Economic Research. Vol. 15 (11) p. 155–164.
KOSOV M.E., AKHMADEEV R.G., OSIPOV V.S., KHARAKOZ Y.K., SMOTRITSKAYA I. 2016. Socio-economic planning of the economy. Indian Journal of Science and Technology. Vol. 9(36), 102008. DOI 10.17485/ijst/2016/v9i36/102008.
LEHOUX L., DUCK H., AKHMADEEV R., MOROZOVA T., BYKANOVA O. 2019. Sustainable development facets: Taxation solutions for the energy industry. Journal of Security & Sustainability Issues. Vol. 9(2) p. 457–472. DOI 10.9770/jssi. 2019.9.2(8).
MAGELSSEN C., SANCHEZ F., DAMANPOUR F. 2015. Learning from outsourcing: the effects of outsourcing strategy on organizational efficiency. Academy of Management Proceedings. Vol. 1 p. 17468. DOI 10.5465/ambpp.2015.262.
MARMILOVA E., KASHIRSKAYA L., KUBENKA M., TURGAEVA A., ZURNADZHYANTS YU., PRODANOVA N. 2020. Methods for conducting an audit of the effectiveness of internal control. Journal of Security and Sustainability Issues. Vol. 9(M) p. 433–450. DOI 10.9770/jssi.2020.9.M(33).
MOROZOVA T., AKHMADEEV R.G., LEHOUX L., YUMASHEV A.V., MESHKOVA G.V., LUKYANOVA M.N. 2020. Crypto asset assessment models in financial reporting content typologies. Entrepreneurship and Sustainability Issues. Vol. 7(3) p. 2196–2212. DOI 10.9770/jesi.2020.7.3(49).
PANFILOVA E., DZENZELIUK N., DOMNINA O., MORGUNOVA N., ZATSARINNAYA E. 2020. The impact of cost allocation on key decisions of supply chain participants. International Journal of Supply Chain Management. Vol. 9 (1) p. 552–558.
PETRENKO Y., VECHKINZOVA E., ANTONOV V. 2019. Transition from the industrial clusters to the smart specialization: A case study. Insights into Regional Development. Vol. 1(2) p. 118–128. DOI 10.9770/ird.2019.1.2(3).
PINGALE S., ADAMOWSKI J., JAT M., KHARE D. 2015. Implications of spatial scale on climate change assessments. Journal of Water and Land Development. No. 26(1) p. 37–55. DOI 10.1515/jwld-2015-0015.
POLLITT C. 2013. 40 years of public management reform in UK central government–promises, promises... Policy and Politics. Vol. 41 (4) p. 465–480. DOI 10.1332/030557312X655710.
PRODANOVA N., SAVINA N., KEVORKOVA Z., KORSHUNOVA L., BOCHKAREVA N. 2019. Organizational and methodological support of corporate self-assessment procedure as a basis for sustainable business development. Entrepreneurship and Sustainability Issues. Vol. 7(2) p. 1136–1148. DOI 10.9770/jesi. 2019.7.2(24).
PURYAEV A. 2020. About the essence of categories “Efficiency” and “Efficiency of the Investment Project” . Proceeding of the International Science and Technology Conference “FarEastСon 2019”. Springer p. 643–651. DOI 10.1007/978-981-15-2244-4_60.
PURYAEV A., PURYAEV A. 2020. Evaluating the effectiveness of projects of global and national economic significance level. Proceeding of the International Science and Technology Conference “FarEastСon 2019”. Springer p. 317–331. DOI 10.1007/978-981-15-2244-4_29.
RUSAW A.C. 2007. Changing public organizations: Four approaches. International Journal of Public Administration. Vol. 30(3) p. 347–361. DOI 10.1080/01900690601117853.
VERTAKOVA Y., MKRTCHYAN V., LEONTYEV E. 2019. Information provision of decision support systems in conditions of structural changes and digitalization of the economy. Journal of Applied Engineering Science. Vol. 17(1) p. 74–80. DOI 10.5937/jaes16-18131.
VLASOV A.I., JURAVLEVA L.V., SHAKHNOV V.A. 2019. Visual environment of cognitive graphics for end-to-end engineering project-based education. Journal of Applied Engineering Science. Vol. 17(1) p. 99–106. DOI 10.5937/jaes17-20262.
ZEIBOTE Z., VOLKOVA T., TODOROV K. 2019. The impact of globalization on regional development and competitiveness: cases of selected regions. Entrepreneurship and Sustainability Center. Vol. 1(1) p. 33–47. DOI 10.9770/ird.2019.1.1(3)

Go to article

Authors and Affiliations

Lyazzat Sembiyeva
1 2
ORCID: ORCID
Madina Serikova
2
ORCID: ORCID
Katira Satymbekova
3
ORCID: ORCID
Zhanat Tulegenova
4
ORCID: ORCID
Begzat Nurmaganbetova
5
Aida Zhagyparova
2
  1. South Ural State University, prosp. Lenina, 76, Chelyabinsk 454080, Russia
  2. L.N. Gumilyov Eurasian National University, Nur-Sultan (Astana), Kazakhstan
  3. M. Auezov South Kazakhstan State University, Shymkent, Kazakhstan
  4. Turan-Astana University, Nur-Sultan (Astana), Kazakhstan
  5. Korkyt Ata Kyzylorda State University, Kyzylorda, Kazakhstan

Investigation of Particle Filtration in Aluminium Alloy

B. Baumann A. Keßler E. Hoppach G. Wolf M. Szucki O. Hilger
Archives of Foundry Engineering | 2021 | vo. 21 | No 3 | 70-80 | DOI: 10.24425/afe.2021.138668
Keywords simulation casting filtration particle movement castings defects
Download PDF Download RIS Download Bibtex

Abstract

The objective of this work is to gain a deeper understanding of the separation effects and particle movement during filtration of non-metallic inclusions in aluminum casting on a macroscopic level. To understand particle movement, complex simulations are performed using Flow 3D. One focus is the influence of the filter position in the casting system with regard to filtration efficiency. For this purpose, a real filter geometry is scanned with computed tomography (CT) and integrated into the simulation as an STL file. This allows the filtration processes of particles to be represented as realistically as possible. The models provide a look inside the casting system and the flow conditions before, in, and after the filter, which cannot be mapped in real casting tests. In the second part of this work, the casting models used in the simulation are replicated and cast in real casting trials. In order to gain further knowledge about filtration and particle movement, non-metallic particles are added to the melt and then separated by a filter. These particles are then detected in the filter by metallographic analysis. The numerical simulations of particle movement in an aluminum melt during filtration, give predictions in reasonable agreement with experimental measurements.
Go to article

Bibliography

[1] Ishikawa, K., Okuda, H. & Kobayashi, Y. (1997). Creep behaviors of highly pure aluminum at lower temperatures. Materials Science and Engineering A. 234-236, 154-156.
[2] Ishikawa, K. & Kobayashi, Y. (2004). Creep and rupture behavior of a commercial aluminum-magnesium alloy A5083 at constant applied stress. Materials Science and Engineering A, 387-389, 613-617.
[3] Dobes, F. & Milicka, K. (2004). Comparison of thermally activated overcoming of barriers in creep of aluminum and its solid solutions. Materials Science and Engineering A. 387-389, 595-598.
[4] Requena, G. & Degischer, H.P. (2006). Creep behavior of unreinforced and short fiber reinforced AlSi12CuMgNi piston alloy. Materials Science and Engineering A. 420, 265-275.
[5] Li, L.T., Lin, Y.C., Zhou, H.M. & Jiang, Y.Q. (2013). Modeling the high-temperature creep behaviors of 7075 and 2124 aluminum alloys by continuum damage mechanics model. Computational Materials Science. 73, 72-78.
[6] Fernandez-Gutierrez, R. & Requena, G.C. (2014). The effect of spheroidization heat treatment on the creep resistance of a cast AlSi12CuMgNi piston alloy. Materials Science and Engineering A. 598, 147-153.
[7] Zhang, Q., Zhang, W. & Liu, Y. (2015). Evaluation and mathematical modeling of asymmetric tensile and compressive creep in aluminum alloy ZL109. Materials Science and Engineering A. 628, 340-349.
[8] Wang, Q., Zhang, L., Xu, Y., Liu, C., Zhao, X., Xu, L., Yang, Y. & Cia, Y. (2020). Creep aging behavior of retrogression and re-aged 7150 aluminum alloy. Transactions of Nonferrous Metals Society of China. 30(10), 2599-2612.
[9] Ahn, C., Jo, I., Ji, C., Cho, S., Mishra, B. & Lee, E. (2020). Creep behavior of high-pressure die-cast AlSi10MnMg aluminum alloy. Materials Characterization. 167, 110495.
[10] Zhang, M., Lewis, R.J. & Gibeling, J.C. (2021). Mechanisms of creep deformation in a rapidly solidified Al-Fe-V-Si alloy. Materials Science and Engineering A. 805, 140796.
[11] Golshan, A.M.A., Aroo, H. & Azadi, M. (2021). Sensitivity analysis for effects of heat treatment, stress, and temperature on AlSi12CuNiMg aluminum alloy behavior under force-controlled creep loading. Applied Physics A. 127, 48.
[12] Pal, K., Navin, K. & Kurchania, R. (2020). Study of structural and mechanical behavior of Al-ZrO2 metal matrix nano-composites prepared by powder metallurgy method. Materials today: Proceeding. 26(Part 2), 2714-2719.
[13] Shuvho, M.B.A. Chowdhury, M.A., Kchaou, M., Rahman, A. & Islam, M.A. (2020). Surface characterization and mechanical behavior of aluminum-based metal matrix composite reinforced with nano Al2O3, SiC, TiO2 particles. Chemical Data Collections. 28, 100442.
[14] Azadi, M. & Aroo, H. (2019).Creep properties and failure mechanisms of aluminum alloy and aluminum matrix silicon oxide nano-composite under working conditions in engine pistons. Materials Research Express. 6, 115020.
[15] Cadek, J., Oikawa, H. & Gustek, V. (1995).Threshold creep behavior of discontinuous aluminum and aluminum alloy matrix composites: an overview. Materials Science and Engineering A. 190, 9-23.
[16] Spigarelli, S. & Paoletti, C. (2018). A new model for the description of creep behavior of aluminum-based composites reinforced with nano-sized particles. Composites Part A. 112, 346-355.
[17] Gupta, R. & Daniel, B.S.S.(2018). Impression creep behavior of ultrasonically processed in-situ Al3Ti reinforced aluminum composite. Materials Science and Engineering A. 733, 257-266.
[18] Gonga, D., Jianga, L., Guanc, J., Liua, K., Yua, Z. & Wua, G. (2020). Stable second phase: the key to high-temperature creep performance of particle reinforced aluminum matrix composite. Materials Science and Engineering A. 770, 138551.
[19] Zhao, Q., Zhang, H., Zhang, X., Qiu, F. & Jiang, Q. (2018). Enhanced elevated-temperature mechanical properties of Al-Mn-Mg containing TiC nano-particles by pre-strain and concurrent precipitation. Materials Science and Engineering A. 718, 305-310.
[20] Bhoi, N., Singh, H. & Pratap, S. (2020). Developments in the aluminum metal matrix composites reinforced by micro/nano-particles - A review. Journal of Composite Materials. 54(6), 813-833.
[21] Azadi, M., Zomorodipour, M. & Fereidoon, A. (2021). Study of effect of loading rate on tensile properties of aluminum alloy and aluminum matrix nano-composite. Journal of Mechanical Engineering. 51(1), 9-18.
[22] Bhowmik, A., Dey, D. & Biswas, A. (2021). Characteristics study of physical, mechanical and tribological behavior of SiC/TiB2 dispersed aluminum matrix composite. Silicon. 06 January. DOI: https://doi.org/10.1007/s12633-020-00923-2.
Go to article

Authors and Affiliations

B. Baumann
1
A. Keßler
1
E. Hoppach
1
G. Wolf
1
M. Szucki
1
ORCID: ORCID
O. Hilger
2
  1. Foundry Institute, Technische Universität Bergakademie Freiberg, 4 Bernhard-von-Cotta-Str., 09599 Freiberg, Germany
  2. Simcast GmbH, Westring 401, 42329 Wuppertal, Germany

This page uses 'cookies'. Learn more