首页|期刊导航|航空学报|保护罩开启时高速飞行器内流场建立过程分析

保护罩开启时高速飞行器内流场建立过程分析OA

Internal flow field development process of a hypersonic vehicle during protective cover separation

中文摘要英文摘要

助推器和保护罩在同一时间从吸气式高超声速飞行器上解锁的"同时分离"时序方案,可利用内流道的充填高压,有利于飞行器的轴向分离过程.然而,在该时序方案分离初期,受运动激波、激波串及气体充填的作用,飞行器内流道中存在复杂多变的压力振荡,除传统的碰撞风险外,还有气体充填导致的潜在超压风险.结合重叠动网格技术,求解非定常雷诺平均Navier-Stokes(RANS)方程,对保护罩开启时飞行器内流道流场的建立过程进行数值计算,获得内流道的时序流场结构和非定常压力特性;分析开罩过程中内流场的演变机理,以及保护罩运动与级间距变化对分离初期流场建立过程的影响机制.结果表明:在"同时分离"时序方案的分离初期,内流道的充填与泄流过程中存在缝隙射流、运动激波扫掠、激波串前移、气体倒流与泄流过渡5个流动特征显著不同的阶段;保护罩开启时,内流道出现最大压力的主要因素是激波系增压、激波串增压和气体充填蓄压,并非是运动激波引起的压力跃升;内流道是否起动,决定了保护罩运动与级间距变化对内流道流场的作用是单向依赖关系还是耦合作用关系.

The"simultaneous separation"sequence,involving the concurrent unlocking of the booster and protective cover from an air-breathing hypersonic vehicle,facilitates axial separation by utilizing the pressurized gas filling of the internal flow path.However,during the initial separation phase under this sequence,complex and variable pressure oscillations arise within the vehicle's internal flow path due to the interaction of moving shock waves,shock trains,and gas filling.Beyond conventional collision risks,a potential overpressure risk from the gas filling process is introduced into this sequence.Numerical simulations of developing flow field within the vehicle's internal flow path during protec-tive cover separation were carried out,using overset moving mesh technology and solving the unsteady Reynolds-Averaged Navier-Stokes(RANS)equations.The temporal flow field structures and unsteady pressure characteristics within the internal flow path were obtained.The evolution mechanism of the internal flow field during protective cover separation,as well as the influence mechanism between protective cover motion and stage distance variation on the flow field development during initial separation phase,were analyzed.The results indicate that during the initial sepa-ration phase under the"simultaneous separation"sequence,the filling and venting process of the internal flow path exhibits five distinct stages characterized by significantly different flow phenomena:gap-induced jet flow,moving shock sweep,shock train forward movement,gas backflow,and venting transition.The maximum pressure observed within the internal flow path during protective cover separation is primarily attributable to shock system pressurization,shock train pressurization,and gas filling pressurization/accumulation,rather than the pressure jump induced by the moving shock.The operational state of the internal flow path,whether started or unstarted,determines if the influence of cover motion and stage distance variation on the internal flow field manifests as a unidirectional dependency or a coupled interaction relationship.

钟俊;范晓樯;熊冰;陈磊;唐啸

国防科技大学 先进推进技术实验室,长沙 410073||中国空气动力研究与发展中心 超高速空气动力研究所,绵阳 621000||飞行器流体物理全国重点实验室,绵阳 621000国防科技大学 先进推进技术实验室,长沙 410073国防科技大学 先进推进技术实验室,长沙 410073国防科技大学 先进推进技术实验室,长沙 410073国防科技大学 先进推进技术实验室,长沙 410073

航空航天

保护罩内流场多体分离气体充填压力特性非定常流动

protective coverinternal flow fieldmulti-body separationgas fillingpressure characteristicsun-steady flow

《航空学报》 2026 (8)

35-51,17

国家自然科学基金(12372298) National Natural Science Foundation of China(12372298)

10.7527/S1000-6893.2025.32638

评论