Bir Keşif Uçuş Zarfı Boyunca Bir İHA’nın Ekserji Haritalaması

Bu çalışmada, bir insansız hava aracının (İHA) keşif uçuşu sırasında ekserji haritalaması incelenmiştir. Literatürde ilk kez tam uçuş zarfını (kalkıştan inişe kadar) kapsayan taşıma ekserjisi yönteminin uygulanması için bir turboprop İHA seçilmiştir. Taşıma ekserjisi yönteminden elde edilen sonuçlar, bu yöntemin bir İHA ve bileşenlerinde ekserji yıkımını analiz etmek için faydalı bir araç olduğunu göstermiştir. Ekserji yıkım seviyesi farklı uçuş noktalarındaki sonuçlar karşılaştırılarak sunulmuş, tırmanışın başlangıcında maksimum ve keşif sırasında minimum olduğu görülmüştür. Benzer şekilde, İHA alt sistemlerindeki ekserji yıkımı karşılaştırmalı olarak hesaplanmış ve motor alt sisteminin en yüksek olduğu gösterilmiştir. Ayrıca, tüm İHA alt sistemleri için taşıma ekserji tüketimi sunulmuş ve yakıt ve gövde alt sistemlerinin en yüksek taşıma enerjisini tükettiği hesaplanmıştır. Taşıma ekserjisi yöntemi, bu çalışma ışığında gelecekte yapılacak çalışmalar için yolcu uçakları, askeri uçaklar vb. farklı hava araçlarının değerlendirilmesinde kullanılabilir.

Exergy Mapping of a UAV Through a Reconnaissance Flight Envelope

In this study, exergy mapping of an unmanned aerial vehicle (UAV) is investigated during its reconnaissance flight. A turboprop UAV is selected for the application of the exergy of lift method covering a full flight envelope (from takeoff to landing) for the first time in the literature. The results from the lift exergy method show that this method is an advantageous instrument to analyze the destruction of exergy in a UAV and its components. The exergy destruction level is presented by comparing the results at different flight points, and it is seen that it is at a maximum at the beginning of the climb and a minimum during the loiter. Similarly, exergy destruction in UAV subsystems is calculated comparatively and it is shown that the engine subsystem is the highest. In addition, the lift exergy consumption is presented for all UAV subsystems and it is calculated that fuel and fuselage subsystems consume the highest lift exergy. The method of exergy of lift can be used for assessment of different air vehicles, such as passenger aircraft, military aircraft, and others. for future studies in light of this study.

PDF

___

[1] L. Newcome, Unmanned aviation: A brief history of unmanned aerial vehicles. Virginia: American Institute of Aeronautics and Astronautics, 2004.
[2] B. Fan, Y. Li, R. Zhang and Q. Fu, “Review on the Technological Development and Application of UAV Systems”, Chinese Journal of Electronics, vol. 29, pp. 199-207, March 2020
[3] M. Sadraey, Unmanned Aircraft Design: A Review of Fundamentals. California: Morgan & Claypool Publishers, 2017.
[4] A. Korchenko and O. Illyash, “The generalized classification of Unmanned Air Vehicles”, in 2013 IEEE 2nd International Conference Actual Problems of Unmanned Air Vehicles Developments (APUAVD), Kyiv, Ukraine, 15-17 October 2013, p. 14030141
[5] D. Tsouros, S. Bibi and P. Sarigiannidis, “A Review on UAV-Based Applications for Precision Agriculture”, Information, vol. 10, pp. 349-375, October 2019.
[6] P. Chen and Y. Zhou, “The Review of Target Tracking for UAV”, in 2019 14th IEEE Conference on Industrial Electronics and Applications (ICIEA), Xi’an, China, 19-21 June 2019, p. 18992990.
[7] S. Kontogiannis and J. Ekaterinaris, “Design, performance evaluation and optimization of a UAV”, Aerospace Science and Technology, vol. 29, pp. 339-350, August 2013.
[8] P. Panagiotou, S. Fotiadis-Karras and K. Yakinthos, “Conceptual design of a Blended Wing Body MALE UAV”, Aerospace Science and Technology, vol. 73, pp. 32-47, February 2018.
[9] Ö. Dündar, M. Bilici and T. Ünler, “Design and performance analyses of a fixed-wing battery VTOL UAV”, Engineering Science and Technology, an International Journal, vol. 23, pp. 1182-1193, October 2020.
[10] Y. Azabi, A. Savvaris and T. Kipouros, “Initial Investigation of Aerodynamic Shape Design Optimisation for the Aegis UAV”, Transportation Research Procedia, vol. 29, pp. 12-22, February 2018.
[11] P. Boschetti, E. Cárdenas and A. Amerio, “Aerodynamic Optimization of an UAV Design”, in AIAA 5th ATIO and16th Lighter-Than-Air Sys Tech. and Balloon Systems Conferences, Arlington, Virginia, USA, 26-28 September 2005, pp. 1-17.
[12] C. Larsen, S. Paul, A. Svensson and S. Chowdhury, “Optimizing Endurance and Stability of a Modular UAV Design”, in 55th AIAA Aerospace Sciences Meeting, Grapevine, Texas, USA, 9-13 January 2013, pp. 1-16.
[13] A. Papageorgiou, J. Ölvander and K. Amadori, “Development of a Multidisciplinary Design Optimization Framework Applied on UAV Design by Considering Models for Mission, Surveillance, and Stealth Performance”, in 18th AIAA/ISSMO Multidisciplinary Analysis and Optimization Conference, Denver, Colorado, USA, 5-9 June 2017, No. AIAA-2017-4151.
[14] P. Panagiotou, D. Mitridis, T. Dimopoulos, S. Kapsalis, S. Dimitriou and K. Yakinthos, “Aerodynamic design of a tactical Blended-WingBody UAV for the aerial delivery of cargo and lifesaving supplies”, in AIAA Scitech 2020 Forum, Orlando, Florida, USA, 6-10 January 2020, No. AIAA2020-1958.
[15] A. Dinc and M. Moayyedian, “Predicting Maximum Endurance of a High Altitude Long Endurance UAV With Taguchi Method”, International Journal of Innovations in Engineering Research and Technology, vol. 6, pp. 1-7, March 2021.
[16] A.S. Akgül and A. Hacioğlu, “To Design and Build of a Surveillance/Attack Mini Unmanned Aerial Vehicle (UAV)”, Journal of Aeronautics & Space Technologies, vol. 4, pp. 1-6, January 2010.
[17] A. Dinc, “Optimization of a Turboprop UAV for Maximum Loiter and Specific Power Using Genetic Algorithm”, International Journal of Turbo & JetEngines, vol. 33, pp. 265-273, August 2016.
[18] A. Dinc, “Sizing of a Turboprop Unmanned Air Vehicle and Its Propulsion System”, Journal of Thermal Science and Technology, vol. 35, pp. 53-62, June 2015.
[19] A. Bejan and D. Siems, “The need for exergy analysis and thermodynamic optimization in aircraft development”, Exergy, An International Journal, vol. 1, pp. 14-24, July 2001.
[20] J. Ordonez, “Minimum power requirement for environmental control of aircraft”, Energy, vol. 28, pp. 1183-1202, October 2003.
[21] D. Riggins, D. Moorhouse and J. Camberos, “Characterization of Aerospace Vehicle Performance and Mission Analysis Using Thermodynamic Availability”, Journal of Aircraft, vol. 47, pp. 904-916, May 2010.
[22] Y. Şöhret, S. Ekici, Ö. Altuntaş, A. Hepbasli and T. Karakoç, “Exergy as a useful tool for the performance assessment of aircraft gas turbine engines: A key review”, Progress in Aerospace Sciences, vol. 83, pp. 57-69, May 2016.
[23] D. Hayes, M. Lone, J. Whidborne, J. Camberos and E. Coetzee, “Adopting exergy analysis for use in aerospace”, Progress in Aerospace Sciences, vol. 93, pp. 73-94, August 2017.
[24] F. Berg, M. Balchin and P. Keogh, “New Principles for Dynamic Aircraft Exergy Mapping”, Journal of Aircraft, vol. 50, pp. 1088-1098, July 2013.
[25] I. Dincer and Y. Cengel, “Energy, Entropy and Exergy Concepts and Their Roles in Thermal Engineering”, Entropy, vol. 3, pp. 116–149, September 2001.
26] I. Dincer and M. Rosen, “Exergy as a Driver for Achieving Sustainability”, International Journal of Green Energy, vol. 1, pp. 1-19, February 2004.
[27] E. Sciubba and G. Wall, “A brief Commented History of Exergy From the Beginnings to 2004”, International Journal of Thermodynamics, vol. 10, pp. 1-26, March 2007.
[28] G. Tsatsaronis, “Definitions and nomenclature in exergy analysis and exergoeconomics”, Energy, vol. 32, pp. 249-253, April 2007.
[29] I. Dincer and T. Ratlamwala, “Importance of exergy for analysis, improvement, design, and assessment”, Wiley Interdisciplinary Reviews: Energy and Environment, vol. 2, pp. 335-349, May 2013.
[30] Y. Şöhret, “A comprehensive approach to understanding irreversibility in a turbojet”, Propulsion and Power Research, vol. 7, pp. 129-137, June 2018.
[31] Y. Şöhret, “Exergo-Sustainability Analysis And Ecological Function Of A Simple Gas Turbine AeroEngine”, Journal of Thermal Engineering, vol. 4, pp. 2083-2095, April 2018.
[32] C. Yücer , “Exergetic Sustainability Assessment Of A Gas Turbine Jet Engine At Part Loads”, Anadolu University Journal of Science and Technology AApplied Sciences and Engineering, vol. 18, pp. 1018- 1030, December 2017.
[33] Y. Şöhret, “Defining the Ecological Coefficient of Performance for an Aircraft Propulsion System”, International Journal of Turbo & JetEngines, vol. 35, pp. 171-180, May 2018.
[34] C. Yücer, “Investigation Of The Performance For A Gas Turbine Jet Engine By Using Exergy Analysis Method”, Nigde Omer Halisdemir University Journal of Engineering Sciences, vol. 8, pp. 405-411, January 2019.
[35] S. Ekici, “Thermodynamic mapping of A321- 200 in terms of performance parameters, sustainability indicators and thermo-ecological performance at various flight phases”, Energy, vol. 202, p. 117692, July 2020.
[36] S. Ekici, “Investigating routes performance of flight profile generated based on the off-design point: Elaboration of commercial aircraft-engine pairing”, Energy, vol. 193, p. 116804, February 2020.
[37] H. Tuzcu, Y. Sohret and H. Caliskan, “Energy, environment and enviroeconomic analyses and assessments of the turbofan engine used in aviation industry”, Environmental Progress & Sustainable Energy, vol. 40, p. e13547, May 2021.
[38] A. Dinc, Y. Şöhret and S. Ekici, “Exergy analysis of a three-spool turboprop engine during the flight of a cargo aircraft”, Aircraft Engineering and Aerospace Technology, vol. 92, pp. 1495-1503, October 2020.
[39] O. Balli and H. Caliskan, “On-design and offdesign operation performance assessments of an aero turboprop engine used on unmanned aerial vehicles (UAVs) in terms of aviation, thermodynamic, environmental and sustainability perspectives”, Energy Conversion and Management, vol. 243, p. 114403, September 2021.
[40] O. Balli and H. Caliskan, “Turbofan engine performances from aviation, thermodynamic and environmental perspectives”, Energy, vol. 232, p. 121031, October 2021.
[41] D. Paulus, Jr. and R. Gaggioli, “The Exergy of Lift and Aircraft Exergy Flow Diagrams”, International Journal of Thermodynamics, vol. 6, pp. 149-156, December 2003.
[42] S. Ayaz, Ö. Altuntaş, and E. Açıkkalp, “The Exergy of Lift During Climb and Cruise for Different Engine Types”, Journal of Aeronautics & Space Technologies, vol. 9, pp. 15-23, January 2016.
[43] Anonymous, "MQ-9A Reaper (Predator B)", General Atomics Aeronautical Systems Inc., 2021. [Online]. Available: https://www.ga-asi.com/remotelypiloted-aircraft/mq-9a. [Accessed: 24- Jun- 2021].

Havacılık ve Uzay Teknolojileri Dergisi-Cover

ISSN: 1304-0448
Yayın Aralığı: Yılda 2 Sayı
Başlangıç: 2003
Yayıncı: Dr. Öğr. Üyesi Fatma Kutlu Gündoğdu

Arşiv

Sayıdaki Diğer Makaleler

Aktif Firar Kenarı Flabının Rotor Palaları Üzerindeki Aerodinamik vePerformans Etkileri

Özge ÖZDEMİR, Hüseyin URAL

Pisagor Bulanık Ortamda Yeni Bir Melez AHP TOPSIS TabanlıYöntemle Uzay İstasyonu Seçimi: Türkiye'den Bir Vaka Çalışması

Turan PAKSOY, Engin Hasan ÇOPUR, Enes DEMİRALAY

Derin Sinir Ağı ve Word2Vec Tabanlı Çok Sınıflı DokümanSınıflandırma

Ali GÜNEŞ, İlkay YELMEN, Zafer ASLAN, Metin ZONTUL

Piezoelektrik Malzemeler Kullanilarak Çeşitli Yükler Altinda DüzPlakalarin Titreşim Kontrolü Üzerine Sayısal Çalışma

Cansu GENÇBAY, Vedat Ziya DOĞAN

Bir Keşif Uçuş Zarfı Boyunca Bir İHA’nın Ekserji Haritalaması

Yasin ŞÖHRET, Ali DİNÇ

Gelişmiş Helikopter Rotor Palaları İçin Çok Disiplinli Kavramsal TasarımMetodu ve Tasarım Aracı

Hasan İBAÇOĞLU, Aytaç ARIKOĞLU