Araştırma Makalesi
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Hidrojen Üretimli Transkritik CO2 Rankine Çevrimi ve Helyum Gaz Türbini Tabanlı Çok Üretimli Sistemin Tasarımı ve Performans Değerlendirmesi

Yıl 2024, , 2297 - 2314, 23.10.2024
https://doi.org/10.29130/dubited.1488860

Öz

Transkritik CO2 Rankine çevrimini (tRC) ve hidrojen (H2) üretimi için bir helyum türbinini (He tur.) birleştiren gaz soğutmalı modüler reaktör (GCMR) ile ilgili nükleer enerjideki çalışmalar, bu alanda önemli bir ilerleme anlamına gelmektedir. Bu araştırma çabası, enerji dönüşüm verimliliğini artırmak ve çok yönlü bir enerji taşıyıcısı olan temiz hidrojen üretmek için çeşitli teknolojileri birleştirmeyi amaçladı. GCMR soğutucusu olarak seçilen helyum, üstün ısı transfer kapasitesi, kimyasal eylemsizlik ve yüksek sıcaklıklarda çalışabilme kapasitesi gibi avantajlı özelliklere sahiptir. Bu özellikler, reaktör çekirdeğinden etkili ısı tahliyesini kolaylaştırır ve hem güç çıkışını hem de enerji verimliliğini artırırken korozyon risklerini azaltır. Bu tasarımın önemli yönü, tRC'nin helyum türbiniyle entegre edilmesi, CO2 Rankine döngüsü yoluyla ek güç üretmek için He türbininden gelen atık ısıdan yararlanılarak enerji dönüşüm verimliliğinin ve kaynak kullanımının maksimuma çıkarılmasında yatmaktadır. Analiz sonuçlarına göre Helyum türbininden elde edilen net güç 241679 kW, tRC’den üretilen net güç ise 9902 kW olarak hesaplanmıştır. Ayrıca geliştirilen bu sistem ile 23.11 kg/h H2 ve 183.4 kg/h O2 üretilebilmektedir. Sistemin genel enerjetik ve ekserjetik performansı sırasıyla %41.8 ve %54.28 olarak hesaplanırken, toplam ekserji yıkım miktarı 212199 kW olarak belirlenmiştir. Ayrıca analitik bulgular, sistem bileşenleri arasında reaktör çekirdeğinin 91282 kW ile en yüksek ekserji yıkımını, ısı değiştiricinin (HEx) ise 3.56 kW ile en düşük ekserji yıkımını kaydettiğini ortaya koymaktadır. Ayrıca bu çalışmada, helyum çıkış sıcaklık analizi ve basınç oranının sistem performansına etkisini belirlemek amacıyla parametrik analizler de yapılmıştır.

Kaynakça

  • [1] Energy Economics. (2024, January 5). Energy Charting Tool [Online]. Available: https://www.bp.com/en/global/corporate/energy-economics.html
  • [2] Q. Wang, C. Lu, R. Luo, D. Li, and R.M. Juan, "Thermodynamic analysis and optimization of the combined supercritical carbon dioxide Brayton cycle and organic Rankine cycle-based nuclear hydrogen production system," Energy Research, pp. 832–859, 2022.
  • [3] X. Wang, and Y. Dai, "An exergoeconomic assessment of waste heat recovery from a Gas Turbine-Modular Helium Reactor using two transcritical CO2 cycles," Energy Conversion and Management, vol. 126, pp. 561–572, 2016.
  • [4] I. Dincer, and C. Acar, "A review on clean energy solutions for better sustainability," Energy Research, pp. 585–606, 2015.
  • [5] I. Dincer, "Green methods for hydrogen production," Int J Hydrogen Energy, vol. 37, pp. 1954–71, 2011.
  • [6] S. Sümer, and S. Hacı Mehmet, "Generation-IV reactors and nuclear hydrogen production," Int J Hydrogen Energy, vol. 46, pp. 28963-28948, 2021.
  • [7] S. Dardour, S. Nisan, and F. Charbit, "Utilisation of waste heat from GT – MHR and PBMR reactors for nuclear desalination," Desalination, vol. 205, pp. 254–268, 2007.
  • [8] M.S, El-Genk, and J. Tournier, "On the use of noble gases and binary mixtures as reactor coolants and CBC working fluids," Energy Conversion and Management, vol. 49, pp. 1882–1891, 2008.
  • [9] J.P. Tournier, and M.S El-Genk, "Properties of noble gases and binary mixtures for closed Brayton Cycle applications," Energy Conversion and Management, vol. 49, pp. 469–92, 2008.
  • [10] H. Zhao, and P.F. Peterson, "Multiple reheat helium Brayton cycles for sodium cooled fast reactors," Nuclear Engineering and Design, vol. 238, pp. 1535–46, 2008.
  • [11] M. Temiz, and I. Dincer, "Design and analysis of a new renewable-nuclear hybrid energy system for production of hydrogen, fresh water and power," e-Prime- Advances in Electrical Engineering, Electronics and Energy, vol.1, p. 100021, 2021.
  • [12] M, Temiz, and I. Dincer, "Solar and sodium fast reactor-based integrated energy system developed with thermal energy storage and hydrogen," Energy, vol. 284, pp. 129275, 2023.
  • [13] P. Kowalik, "Advancing production of hydrogen using nuclear cycles - integration of high temperature gas-cooled reactors with thermochemical water splitting cycles," Int J Hydrogen Energy, vol. 52, pp. 1070-1083, 2024.
  • [14] Y. Khan, D. Singh, H. Caliskan, and H. Hong, "Exergoeconomic and thermodynamic analyses of solar power tower based novel combined helium Brayton cycle-transcritical CO2 cycle for carbon free power generation," Global Challenges, pp. 1–16, 2023.
  • [15] M. Temiz, and I. Dincer, "Development of an HTR-Type nuclear and bifacial PV solar based integrated system to meet the needs of energy , food and fuel for sustainable indigenous cities," Sustain Cities Soc, vol. 74, pp. 103198, 2023.
  • [16] J. Gauthier, G. Brinkmann, B. Copsey, and M. Lecomte, "ANTARES : The HTR / VHTR project at Framatome ANP," Nuclear Engineering and Design, vol. 236, pp. 526–33, 2006.
  • [17] Wang, C., Ballinger, R.G., Stahle, P.W., Demetri, E., & Koronowski, M., "Design of a power conversion system for an indirect cycle, helium cooled pebble bed reactor system (INIS-XA--524)". International Atomic Energy Agency (IAEA), 2002.
  • [18] G. Soyturk, O. Kizilkan, M.A. Ezan, and C.O. Colpan, "PVT integrated hydrogen production with small-scale transcritical power cycle," Process Saf Environ Prot, vol. 180, pp. 351–360, 2023.
  • [19] F-Chart, Engineering Equation Solver (EES), S.A. Klein, 2020.
  • [20] Y.A. Cengel, and M.A. Boles, Thermodynamics: An Engineering Approach, 5th ed, McGraw-Hill, 2006.
  • [21] I. Dincer, and M.A. Rosen, Exergy Energy, Environment and Sustainable Development, Hand Book, Elsevier, London, 2007.
  • [22] T. Ioroi, K. Yasuda, Z. Siroma, N. Fujiwara, and Y. Miyazaki, "Thin film electrocatalyst layer for unitized regenerative polymer electrolyte fuel cells," Journal of Power Sources, vol. 112, 583–587, 2002.
  • [23] P. Ahmadi, I. Dincer, and M.A. Rosen, "Multi-objective optimization of an ocean thermal energy conversion system for hydrogen production," Int J Hydrogen Energy, vol. 40, pp. 7601–7608. 2014.

Design and Performance Evaluation of Multi-Generation System based on Transcritical CO2 Rankine Cycle and Helium Gas Turbine with Hydrogen Production

Yıl 2024, , 2297 - 2314, 23.10.2024
https://doi.org/10.29130/dubited.1488860

Öz

The advancement in nuclear energy embodied by the gas-cooled modular reactor (GCMR), incorporating the transcritical CO2 Rankine cycle (tRC) and a helium turbine (He tur.) for hydrogen (H2) production, signifies a substantial leap forward in this domain. This research endeavor aimed to amalgamate various technologies to enhance energy conversion efficiency and generate clean hydrogen, a versatile energy carrier. Helium, selected as the GCMR coolant, boasts advantageous properties such as superior heat transfer capabilities, chemical inertness, and the capacity to operate at elevated temperatures. These attributes facilitate effective heat extraction from the reactor core, mitigating corrosion risks while boosting both power output and energy efficiency. A pivotal aspect of this design lies in integrating the tRC with the helium turbine, maximizing energy conversion efficiency and resource utilization by harnessing waste heat from the He turbine to generate additional power through the CO2 Rankine cycle. Furthermore, the system incorporates a hydrogen production module, enabling the clean generation of hydrogen as a byproduct of the nuclear power generation process. According to analysis results, the net power obtained from the Helium turbine was calculated as 241679 kW, and the net power produced from the tRC was calculated as 9902 kW. Additionally, with this developed system, 23.11 kg/h H2 and 183.4 kg/h O2 can be produced. The energetic and exergetic performance of the overall system is computed as 41.8% and 54.28%, while the total amount of exergy destruction is determined as 212199 kW. Moreover, analytical findings reveal that the reactor core exhibits the highest exergy destruction among system components at 91282 kW, whereas the heat exchanger (HEx) registers the lowest exergy destruction at 3.56 kW. In addition, in this study, parametric analyses are also performed to determine the effect of helium outlet temperature analysis and pressure ratio on system performance.

Kaynakça

  • [1] Energy Economics. (2024, January 5). Energy Charting Tool [Online]. Available: https://www.bp.com/en/global/corporate/energy-economics.html
  • [2] Q. Wang, C. Lu, R. Luo, D. Li, and R.M. Juan, "Thermodynamic analysis and optimization of the combined supercritical carbon dioxide Brayton cycle and organic Rankine cycle-based nuclear hydrogen production system," Energy Research, pp. 832–859, 2022.
  • [3] X. Wang, and Y. Dai, "An exergoeconomic assessment of waste heat recovery from a Gas Turbine-Modular Helium Reactor using two transcritical CO2 cycles," Energy Conversion and Management, vol. 126, pp. 561–572, 2016.
  • [4] I. Dincer, and C. Acar, "A review on clean energy solutions for better sustainability," Energy Research, pp. 585–606, 2015.
  • [5] I. Dincer, "Green methods for hydrogen production," Int J Hydrogen Energy, vol. 37, pp. 1954–71, 2011.
  • [6] S. Sümer, and S. Hacı Mehmet, "Generation-IV reactors and nuclear hydrogen production," Int J Hydrogen Energy, vol. 46, pp. 28963-28948, 2021.
  • [7] S. Dardour, S. Nisan, and F. Charbit, "Utilisation of waste heat from GT – MHR and PBMR reactors for nuclear desalination," Desalination, vol. 205, pp. 254–268, 2007.
  • [8] M.S, El-Genk, and J. Tournier, "On the use of noble gases and binary mixtures as reactor coolants and CBC working fluids," Energy Conversion and Management, vol. 49, pp. 1882–1891, 2008.
  • [9] J.P. Tournier, and M.S El-Genk, "Properties of noble gases and binary mixtures for closed Brayton Cycle applications," Energy Conversion and Management, vol. 49, pp. 469–92, 2008.
  • [10] H. Zhao, and P.F. Peterson, "Multiple reheat helium Brayton cycles for sodium cooled fast reactors," Nuclear Engineering and Design, vol. 238, pp. 1535–46, 2008.
  • [11] M. Temiz, and I. Dincer, "Design and analysis of a new renewable-nuclear hybrid energy system for production of hydrogen, fresh water and power," e-Prime- Advances in Electrical Engineering, Electronics and Energy, vol.1, p. 100021, 2021.
  • [12] M, Temiz, and I. Dincer, "Solar and sodium fast reactor-based integrated energy system developed with thermal energy storage and hydrogen," Energy, vol. 284, pp. 129275, 2023.
  • [13] P. Kowalik, "Advancing production of hydrogen using nuclear cycles - integration of high temperature gas-cooled reactors with thermochemical water splitting cycles," Int J Hydrogen Energy, vol. 52, pp. 1070-1083, 2024.
  • [14] Y. Khan, D. Singh, H. Caliskan, and H. Hong, "Exergoeconomic and thermodynamic analyses of solar power tower based novel combined helium Brayton cycle-transcritical CO2 cycle for carbon free power generation," Global Challenges, pp. 1–16, 2023.
  • [15] M. Temiz, and I. Dincer, "Development of an HTR-Type nuclear and bifacial PV solar based integrated system to meet the needs of energy , food and fuel for sustainable indigenous cities," Sustain Cities Soc, vol. 74, pp. 103198, 2023.
  • [16] J. Gauthier, G. Brinkmann, B. Copsey, and M. Lecomte, "ANTARES : The HTR / VHTR project at Framatome ANP," Nuclear Engineering and Design, vol. 236, pp. 526–33, 2006.
  • [17] Wang, C., Ballinger, R.G., Stahle, P.W., Demetri, E., & Koronowski, M., "Design of a power conversion system for an indirect cycle, helium cooled pebble bed reactor system (INIS-XA--524)". International Atomic Energy Agency (IAEA), 2002.
  • [18] G. Soyturk, O. Kizilkan, M.A. Ezan, and C.O. Colpan, "PVT integrated hydrogen production with small-scale transcritical power cycle," Process Saf Environ Prot, vol. 180, pp. 351–360, 2023.
  • [19] F-Chart, Engineering Equation Solver (EES), S.A. Klein, 2020.
  • [20] Y.A. Cengel, and M.A. Boles, Thermodynamics: An Engineering Approach, 5th ed, McGraw-Hill, 2006.
  • [21] I. Dincer, and M.A. Rosen, Exergy Energy, Environment and Sustainable Development, Hand Book, Elsevier, London, 2007.
  • [22] T. Ioroi, K. Yasuda, Z. Siroma, N. Fujiwara, and Y. Miyazaki, "Thin film electrocatalyst layer for unitized regenerative polymer electrolyte fuel cells," Journal of Power Sources, vol. 112, 583–587, 2002.
  • [23] P. Ahmadi, I. Dincer, and M.A. Rosen, "Multi-objective optimization of an ocean thermal energy conversion system for hydrogen production," Int J Hydrogen Energy, vol. 40, pp. 7601–7608. 2014.
Toplam 23 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Kimyasal Termodinamik ve Enerji Bilimi, Enerji Üretimi, Dönüşüm ve Depolama (Kimyasal ve Elektiksel hariç)
Bölüm Makaleler
Yazarlar

Gamze Soytürk 0000-0001-7191-8765

Yayımlanma Tarihi 23 Ekim 2024
Gönderilme Tarihi 23 Mayıs 2024
Kabul Tarihi 8 Ağustos 2024
Yayımlandığı Sayı Yıl 2024

Kaynak Göster

APA Soytürk, G. (2024). Design and Performance Evaluation of Multi-Generation System based on Transcritical CO2 Rankine Cycle and Helium Gas Turbine with Hydrogen Production. Duzce University Journal of Science and Technology, 12(4), 2297-2314. https://doi.org/10.29130/dubited.1488860
AMA Soytürk G. Design and Performance Evaluation of Multi-Generation System based on Transcritical CO2 Rankine Cycle and Helium Gas Turbine with Hydrogen Production. DÜBİTED. Ekim 2024;12(4):2297-2314. doi:10.29130/dubited.1488860
Chicago Soytürk, Gamze. “Design and Performance Evaluation of Multi-Generation System Based on Transcritical CO2 Rankine Cycle and Helium Gas Turbine With Hydrogen Production”. Duzce University Journal of Science and Technology 12, sy. 4 (Ekim 2024): 2297-2314. https://doi.org/10.29130/dubited.1488860.
EndNote Soytürk G (01 Ekim 2024) Design and Performance Evaluation of Multi-Generation System based on Transcritical CO2 Rankine Cycle and Helium Gas Turbine with Hydrogen Production. Duzce University Journal of Science and Technology 12 4 2297–2314.
IEEE G. Soytürk, “Design and Performance Evaluation of Multi-Generation System based on Transcritical CO2 Rankine Cycle and Helium Gas Turbine with Hydrogen Production”, DÜBİTED, c. 12, sy. 4, ss. 2297–2314, 2024, doi: 10.29130/dubited.1488860.
ISNAD Soytürk, Gamze. “Design and Performance Evaluation of Multi-Generation System Based on Transcritical CO2 Rankine Cycle and Helium Gas Turbine With Hydrogen Production”. Duzce University Journal of Science and Technology 12/4 (Ekim 2024), 2297-2314. https://doi.org/10.29130/dubited.1488860.
JAMA Soytürk G. Design and Performance Evaluation of Multi-Generation System based on Transcritical CO2 Rankine Cycle and Helium Gas Turbine with Hydrogen Production. DÜBİTED. 2024;12:2297–2314.
MLA Soytürk, Gamze. “Design and Performance Evaluation of Multi-Generation System Based on Transcritical CO2 Rankine Cycle and Helium Gas Turbine With Hydrogen Production”. Duzce University Journal of Science and Technology, c. 12, sy. 4, 2024, ss. 2297-14, doi:10.29130/dubited.1488860.
Vancouver Soytürk G. Design and Performance Evaluation of Multi-Generation System based on Transcritical CO2 Rankine Cycle and Helium Gas Turbine with Hydrogen Production. DÜBİTED. 2024;12(4):2297-314.