Micro Gas Turbine Engine for Unmanned Aerial Vehicles

被引:0
|
作者
Sychenkov V.A. [1 ]
Limanskii A.S. [1 ]
Yousef W.M. [1 ]
Ankudimov V.V. [1 ]
Seyid Jafari S.S. [1 ]
机构
[1] Tupolev Kazan National Research Technical University, ul. Karla Marksa 10, Kazan, 420111, Tatarstan
来源
Russian Aeronautics | 2019年 / 62卷 / 04期
关键词
centrifugal compressor; micro gas turbine engine; radial-axial turbine; reverse-flow combustor; turbocharger; unmanned aerial vehicle;
D O I
10.3103/S1068799819040160
中图分类号
学科分类号
摘要
The results of development and manufacture of a micro gas turbine engine for an unmanned aerial vehicle are presented. The calculation features of the main elements of the engine blading section, namely, a centrifugal compressor, a reverse-flow combustor, and a radial-axial turbine are considered. The design of the inlet and output duct, rotor bearings, and lubrication system is described. © 2019, Allerton Press, Inc.
引用
收藏
页码:651 / 660
页数:9
相关论文
共 50 条
  • [21] Low Power Greenhouse Gas Sensors for Unmanned Aerial Vehicles
    Khan, Amir
    Schaefer, David
    Tao, Lei
    Miller, David J.
    Sun, Kang
    Zondlo, Mark A.
    Harrison, William A.
    Roscoe, Bryan
    Lary, David J.
    REMOTE SENSING, 2012, 4 (05) : 1355 - 1368
  • [22] LinkBoard: Advanced Flight Control System for Micro Unmanned Aerial Vehicles
    Wzorek, Mariusz
    Rudol, Piotr
    Conte, Gianpaolo
    Doherty, Patrick
    2017 2ND INTERNATIONAL CONFERENCE ON CONTROL AND ROBOTICS ENGINEERING (ICCRE2017), 2017,
  • [23] Formations of Unmanned Micro Aerial Vehicles Led by Migrating Virtual Leader
    Saska, Martin
    Baca, Tomas
    Hert, Daniel
    2016 14TH INTERNATIONAL CONFERENCE ON CONTROL, AUTOMATION, ROBOTICS AND VISION (ICARCV), 2016,
  • [24] Monitoring of CCS Areas using Micro Unmanned Aerial Vehicles (MUAVs)
    Neumann, P. P.
    Asadi, S.
    Bennetts, V. Hernandez
    Lilienthal, A. J.
    Bartholmai, M.
    GHGT-11, 2013, 37 : 4182 - 4190
  • [25] Monitoring of Forest (Fire) Using Micro Class Unmanned Aerial Vehicles
    Urbahs, A.
    Petuhova, J.
    Urbaha, M.
    Carjova, K.
    Andrejeva, D.
    TRANSPORT MEANS 2013, 2013, : 61 - 65
  • [26] An improved wireless power transmission system for micro unmanned aerial vehicles
    Liu, Shunyu
    Guo, Yuehao
    Su, Ting
    Wu, Haotian
    Xing, Genghao
    Yang, Yongqin
    IET POWER ELECTRONICS, 2024, 17 (14) : 1911 - 1924
  • [27] An altitude measurement unit for micro unmanned aerial vehicles based on barometer
    Ru, Binchao
    Xian, Bin
    Song, Yinglin
    Cao, Meihui
    Zhongnan Daxue Xuebao (Ziran Kexue Ban)/Journal of Central South University (Science and Technology), 2013, 44 (SUPPL.2): : 94 - 97
  • [28] Thermodynamic performance evaluation of a turbine-less jet engine integrated with solid oxide fuel cells for unmanned aerial vehicles
    Ji, Zhixing
    Qin, Jiang
    Cheng, Kunlin
    Dang, Chaolei
    Zhang, Silong
    Dong, Peng
    APPLIED THERMAL ENGINEERING, 2019, 160
  • [29] Combustion characteristics and performance of a Wankel engine for unmanned aerial vehicles at various altitudes
    Kucuk, Merve
    Surmen, Ali
    Sener, Ramazan
    FUEL, 2024, 355
  • [30] One-disk nutating-engine performance for unmanned aerial vehicles
    Korakianitis, T
    Meyer, L
    Boruta, M
    McCormick, HE
    JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER-TRANSACTIONS OF THE ASME, 2004, 126 (03): : 475 - 481
12345