Supersonic flow control via plasma, electric and magnetic impacts

Lapushkina T. A.; Erofeev A. V.

首页> 外文期刊>Aerospace science and technology >Supersonic flow control via plasma, electric and magnetic impacts

【24h】

Supersonic flow control via plasma, electric and magnetic impacts

机译：通过等离子，电磁和电磁冲击进行超音速流控制

获取原文

获取原文并翻译 | 示例

掌桥外文数据库（机构版） >>

开具论文收录证明 >>

文献代查 >>

页面导航

摘要
著录项
相似文献
相关主题

摘要

The possibility to control the shock wave configuration by plasmagasdynamic (PGD), electrogasdynamic (EGD) and magnetohydrodynamic (MHD) methods is presented. In particular, the effects of gas discharges with different parameters on the position and shift of a bow shock wave in the supersonic flow of ionized xenon past a semi-cylinder body are considered. In the plasmagasdynamic control method a discharge creates the strongly non-equilibrium plasma in the flow ahead of the body. In experiments it has been shown that the change in the bow shock-wave position depends on the degree of plasma non-equilibrium. In the EGD and MHD methods, a discharge was organized at the near surface area of the nose part of the body. In these cases the changes in the bow shock wave positions were achieved by changing the discharge intensity (EGD method) or by applying an external magnetic field (MHD method). (C) 2017 Elsevier Masson SAS. All rights reserved.

机译：提出了通过等离子气动力（PGD），电气动力（EGD）和磁流体动力（MHD）方法控制冲击波配置的可能性。特别地，考虑了具有不同参数的气体放电对通过半圆柱体的电离氙气的超音速流动中弓形冲击波的位置和位移的影响。在等离子气体动力学控制方法中，放电会在身体前方的流中产生强烈的非平衡等离子体。在实验中已经表明，弓形冲击波位置的变化取决于等离子体的不平衡程度。在EGD和MHD方法中，放电是在身体鼻子附近的表面区域进行的。在这些情况下，可以通过改变放电强度（EGD方法）或施加外部磁场（MHD方法）来实现船首激波位置的变化。（C）2017 Elsevier Masson SAS。版权所有。

著录项

来源
《Aerospace science and technology》 |2017年第10期|313-320|共8页
作者
Lapushkina T. A.; Erofeev A. V.;
展开▼
作者单位

Ioffe Inst, 26 Polytekhnicheskaya Str, St Petersburg 194021, Russia;

Ioffe Inst, 26 Polytekhnicheskaya Str, St Petersburg 194021, Russia;

展开▼
收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种 eng
中图分类
关键词

相似文献

外文文献
中文文献
专利

1. Active Control of Supersonic Base Flows with Electric Arc Plasma Actuators [J] . Bradley DeBlauw, Gregory Elliott, Craig Dutton AIAA Journal . 2014,第7期

机译：电弧等离子体致动器对超音速基流的主动控制
2. Investigation on Supersonic Flow Control Using Nanosecond Dielectric Barrier Discharge Plasma Actuators [J] . A. Nazarian Shahrbabaki, M. Bazazzadeh, R. Khoshkhoo International journal of aerospace engineering . 2021,第a期

机译：纳秒介质屏障放电等离子体致动器的超声波流量控制研究
3. Observation of plasma microwave emission during the injection of supersonic plasma flows into magnetic arch [J] . Viktorov M. E., Mansfeld D. A., Vodopyanov A. V., Plasma physics and controlled fusion . 2017,第7期

机译：将超声等离子体喷射进入磁拱的血浆微波发射的观察
4. Excitation of Electromagnetic Waves in Dense Plasma During the Injection of Supersonic Plasma Flows into Magnetic Arch [C] . M. E. Viktorov, S. V. Golubev, D. A. Mansfeld, International Conference on Open Magnetic Systems for Plasma Confinement . 2016

机译：将超声等离子体流入磁拱的超音速等离子体中致密等离子体中电磁波的激发
5. Characterization of Plasma Formation and Induced Flows of Nanosecond-Pulsed Dielectric Barrier Discharges for Use in Supersonic Flow Control [D] . Newnam, Kyle 2017

机译：用于超音速流控制的纳秒脉冲介电势垒放电的等离子体形成和诱导流的表征
6. Numerical Laser Energy Deposition on Supersonic Cavity Flow and Sensor Placement Strategies to Control the Flow [O] . Ibrahim Yilmaz, Selin Aradag 2013

机译：超音速腔流动的数值激光能量沉积和控制流动的传感器放置策略
7. Structure of a Magnetic Flux Annihilation Layer Formed by the Collision of Supersonic, Magnetized Plasma Flows [O] . Suttle, LG, Hare, JD, Lebedev, SV, 2016

机译：超声磁化等离子体流碰撞形成的磁通量湮灭层的结构
8. Supersonic Flow of Inviscid Compressible Plasmas with a Finite Tensor Conductivity in the Presence of an External Magnetic Field [R] . Shih, L. Y. 1966

机译：在外磁场存在下具有有限张量电导率的无粘性可压缩等离子体的超音速流动

Supersonic flow control via plasma, electric and magnetic impacts

摘要

著录项

相似文献

相关主题

期刊订阅