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Static and dynamic characteristics of supersonic cruise missile with damaged wing

Published online by Cambridge University Press:  30 May 2024

C.F. Zhuo*
Affiliation:
School of Mechanical Engineering, Key Laboratory of Special Engine Technology, Ministry of Education, Nanjing University of Science and Technology, Nanjing, China
Z.R. He
Affiliation:
School of Mechanical Engineering, Key Laboratory of Special Engine Technology, Ministry of Education, Nanjing University of Science and Technology, Nanjing, China
X.B. Ren
Affiliation:
Shanxi North Xing’an Chemical Industry Co, Ltd, Taiyuan, China
Y.K. Wang
Affiliation:
School of Mechanical Engineering, Key Laboratory of Special Engine Technology, Ministry of Education, Nanjing University of Science and Technology, Nanjing, China
*
Corresponding author: C.F. Zhuo; Email: njust203zcf@126.com
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Abstract

Accurately evaluating the aerodynamic performance of the missile with damaged structures is very important for the subsequent flight control strategy. At present, few researchers have studied the aerodynamic characteristics of damaged supersonic cruise missiles. Based on CFD (computational fluid dynamics) solutions and the dynamic derivative identification method, the differences in static and dynamic characteristics between the damaged and undamaged models are compared. The results indicate that when the extent of damage increases, the change rate of drag coefficient at larger AoA (angle-of-attack) is greater than that at the smaller AoA. On the contrary, the change rate of lift coefficient at larger AoA is smaller than that at smaller AoA. Meanwhile, the absolute value of the static pitch moment decreases, but the absolute value of the roll moment increases. Damage causes a change in the absolute values of the pitch and roll dynamic derivatives, and the dynamic derivatives do not vary monotonically with the increase of AoA. The turning point occurs at about $\alpha$ = 5°. The areas of the hysteresis loops of the pitch-roll coupling moment increase, which makes the dynamic coupling characteristic between the pitch and roll directions increase. Finally, the maximum allowable damage extent of the missile wing that can achieve static trim is obtained and validated by controlling the deflection of the four rudders.

Type
Research Article
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Royal Aeronautical Society

Nomenclature

$C_{m{\dot{\alpha}}} +{{{C}}_{{{mq}}}}$

combined dynamic derivatives

C d

coefficient of drag

C l

coefficient of lift

C mx

coefficient of roll moment

C my

coefficient of pitch moment

h

wing damage width (m)

k

reduced frequency

l

maximum wing width (m)

Ma

Mach number

$\omega $

oscillation frequency (rad/s)

1.0 Introduction

The rapid and continuous development of aerospace technology has a revolutionary impact on modern warfare. At present, tactical missiles should have the combat characteristics of multi-trajectories, long-range, high precision and strong penetration ability. Therefore, supersonic cruise missile has become one of the research hot spots in various countries, due to it can meet the above requirements. The increasingly complex battlefield environment tests the viability of various missiles, and it is very important that the missiles can fly to a predetermined location [Reference Trisolini, Lewis and Colombo1, Reference Zhang, Yang and Yang2]. These missiles may have various combat damage modes during flight. For example, the fuel explosion leads to the disintegration of the missile, and the missile is hit by several interceptors or debris flying in the air and thus disintegrates [Reference An, Qi, Ji and Lin3]. These kinds of damage are irreparable. However, if only some parts of the missile structures are attacked and damaged, the control system may still use other undamaged parts to keep the flight [Reference Kim, Lee and Tahk4]. In this case, it is significant to accurately evaluate the aerodynamic performance, because it directly determines the further flight ability and influences the next control strategy [Reference Cao, Cao, Zuo, Huo, Qiu and Zuo5, Reference Arif, Ansari and Javed6].

Different interception methods will cause different types and extents of damage to the missile wings. Series of computational analyses and experiments of battle damage configurations have been carried out to evaluate the aerodynamic characteristics. At present, there are few works directly related to missile structural damage. Therefore, the studies of aircraft wing structure damage, which is similar to missile wing damage, also have a certain reference value. Aerodynamic simulation of damaged effects had been conducted to provide an understanding of the control and stability of aircraft with asymmetric damage by Elkarim and Elrahman [Reference Elkarim and Elrahman7]. A mathematical model and guidance algorithms were developed for an anti-tank missile by Harris and Slegers [Reference Harris and Slegers8]. Monte Carlo simulations were performed for each type and location of the damaged mid-body wing. The results indicated that the damage response performance of the missile was extremely sensitive to the radial location of the damage. Irwin and Render [Reference Irwin and Render9] carried out wind tunnel tests on wings to simulate battle damage. Application of gunfire and missile fragmentation effects to solid and hollow wing models were implemented. The detrimental effects of these damages were greater for wings of solid construction. Djellal and Ouibrahim [Reference Djellal and Ouibrahim10] evaluated the impact of wing shooting damage on the performance of typical aircraft models through two experimental studies, as well as how to repair the damage. The results showed the damage caused significant aerodynamic coefficient reduction related to the diameter and location of the holes. Patch repairs can achieve substantial recovery of the aerodynamic losses. Wen et al. [Reference Wen, Yang and Shen11] analysed the aerodynamic characteristics of an aircraft with structural damage by using trim, linearisation, stick-fixed response and disturbance simulation. The results indicated that the damage caused an offset to the centre of gravity and pitch-roll, pitch-yaw coupling. The remaining flight performance was studied by inducing the Remaining Capability Factor. Etemadi et al. [Reference Etemadi, Etemadi, Mani and Pooladsanj12] used CFD and experimental methods to evaluate the aerodynamic characteristics of damaged triangular and star-shaped aerofoils after repair. The results revealed the influence mechanism of structural damage on aircraft aerodynamic force and moment, and demonstrated the importance of shape factor in evaluating the performance. Nonlinear static aeroelastic behaviour of the damaged composite missile fins was investigated by Zkaya and Kayran [Reference Zkaya and Kayran13]. Considering the generation of different damages, two-way coupled fluid-structure interaction (FSI) was carried out to predict the influence of the damage modes on the pressure distribution, lift and deformation of the damaged fin, and compared with that of the undamaged missile fin. A CFD study was carried out on a battle-damaged NACA 641-412 half wing by Yang et al. [Reference Yang, Samad-Suhaeb and Render14]. The previous experimental findings were confirmed. The flow field destroyed by simulated gunfire is asymmetric, and this asymmetry was driven by the spanwise variation of static pressure.

The selection of a set of feasible trim points becomes very important for controlling the aircraft under the influence of unfavourable conditions and failures. Continuation methods and bifurcation analyses were employed to determine the family of feasible level flight trim points of a military aircraft by Shankar [Reference Shankar15]. Elgersma and Morton [Reference Elgersma and Morton16] presented closed-form formulas for computing all possible trim values for six-degree-of-freedom nonlinear aircraft models. The four-dimensional trim set was parameterised by giving at most two real trim values for each set of fixed values. A wind tunnel investigation was conducted to measure the aerodynamic effects of damage to lifting and stability/control surfaces of a commercial transport aircraft by Shah [Reference Shah17]. The author developed flight control systems to recover the aircraft from adverse, damage-related loss of control events and estimated aerodynamic characteristics from flight data.

These studies had further improved the practicability of studying performance on damaged missiles and aircrafts, but there is little research on wing damage of supersonic cruise missiles. Previous studies have showed that the aerodynamic performance of a missile with different types and extents of damage varies greatly. Generally, there are three categories of battle damage to missiles caused by interceptors: fragment, discrete rod and continuous rod damage. The former two have similar effects. Their typical performance is the perforation of missile parts. By comparison, continuous rod damage has a greater killing range and is always able to cut the missile into multiple parts. Considering the small impact of perforation damage on the wing, only one typical continuous rod damage [Reference Mikhail18] effect is analysed in this study. Meanwhile, the most important task for the damaged missile is how to control its flight by using the remaining rudder surfaces and the engine power [Reference Mi19]. Therefore, to optimise the flight control strategy, it is necessary to accurately calculate the aerodynamic performance of the damaged missile. The main contents of this study are as follows. First, the feasibility of the Spalart-Allmaras turbulence model in calculating the static and dynamic aerodynamic characteristics of the missile is validated. Then the aerodynamic characteristics of a simplified missile model after its right wing being damaged to different extents are calculated and compared. The changing rules and reasons are found. After that, the research on the dynamic pitch, roll and pitch-roll coupling characteristics of the damaged missile is emphasised. Finally, the maximum allowable damage extent of the missile wing that can achieve static trim is obtained when the maximum flight angle-of-attack is $\alpha$ = 12° and the maximum deflection angle of the single rudder is $\beta$ = 15°.

2.0 Battle-damaged model and computational grids

2.1 Model

Four extents of the right wing damage are considered. The extent of damage is indicated by the missing wing span length. The maximum damage to the wing is 50%, which represents the worst-case damage reproducible during environmental drops performed by the Close Combat Weapons Systems Project Office and the US Marine Corp [Reference Lanham20]. These parameters may not be consistent with the actual damaged situations, but they help to obtain the relationship between the change of aerodynamic performance and the damage extent of missile wing.

The model used in this study is a simplified version of a typical supersonic cruise missile. In order to conveniently make a comparison before and after damage, the axisymmetric inlet and aerofoil of the model are simplified, and the case of one wing damage is discussed in this paper. The parameters of geometric model are shown in Fig. 1, and they are measured in millimeters. W represents the wing and R represents the rudder in Fig. 1(b). h represents the damaged width in Fig. 1(c).

Figure 1. Geometric model and damage diagram.

The wing of the missile is thin and light, so the change in the centre of gravity can be neglected. The parameters of the missile are shown in Table 1. The reference area is the maximum cross-sectional area of the missile body, and the reference length is the diameter of the missile. The moment reference point (MRP) is 2.5m from the missile head and it is also set as the point of rotation (POR) for dynamic simulation.

Table 1. Basic parameters of missile

2.2 Mesh

The research adopts structured meshes. High-speed compressible flows involve important fluid phenomena typically exhibiting shock waves, rarefactions and related complexities [Reference Struchkov, Kozelkov, Volkov, Kurkin, Zhuckov and Sarazov21]. Therefore, the mesh needs to be encrypted where the flow changes violently. For example, the mesh is encrypted when the geometric structure of the model changes. Figure 2 gives the computational mesh, including far field mesh and boundary layer mesh. The far-field length in the computational domain is 10 times the length and 20 times the diameter of the projectile.

Figure 2. Mesh generation of the missile.

Mesh independence is crucial to get the correct solution. An efficient mesh resolution must be determined to find correct calculation results and the appropriate amount of solution time [Reference Sumnu and Güzelbey22]. The solution in this study is implemented by generating different mesh resolution between about 1.2 and 6.2 million. Figure 3 shows mesh independence for the drag coefficient (C d) versus the number of mesh resolution.

Figure 3. Mesh independence validation.

The calculation result of 6.2 million mesh resolution is used as reference values. Table 2 shows that the change rate of C d is all less than 2%. Since the solution results are negligible changes above 2.85 million mesh resolution, considering the calculation time cost, 2.85 million is chosen as the efficient mesh resolution.

Table 2. Mesh independence error of Cd

3.0 Computational method

3.1 Fluid governing equation

The continuity equation and energy equation are referred to the Ref. [Reference Elisov, Ishkov and Shakhov23]. The conservation form of the 3D dimensionless, unsteady, compressible, Reynolds-averaged Navier–Stokes equations in Cartesian coordinates is as follows [Reference Yang, Wang and Gao24]:

\begin{align*}\frac{{\partial {{\boldsymbol{{Q}}}}}}{{\partial t}} + \frac{{\partial {{\boldsymbol{{F}}}}}}{{\partial x}} + \frac{{\partial {{\boldsymbol{{G}}}}}}{{\partial y}} + \frac{{\partial {{\boldsymbol{{H}}}}}}{{\partial z}} = \left[ {\frac{{\partial {{{\boldsymbol{{F}}}}_v}}}{{\partial x}} + \frac{{\partial {{{\boldsymbol{{G}}}}_v}}}{{\partial y}} + \frac{{\partial {{{\boldsymbol{{H}}}}_v}}}{{\partial z}}} \right]\end{align*}
\begin{align*}{{\boldsymbol{{Q}}}} = \left[ \begin{array}{l}\rho \\[5pt] \rho u\\[5pt] \rho v\\[5pt] \rho w\\[5pt] \rho E\end{array} \right],{{\boldsymbol{{F}}}} = \left[ \begin{array}{l}\rho u\\[5pt] \rho {u^2} + p\\[5pt] \rho uv\\[5pt] \rho uw\\[5pt] \rho Hu\end{array} \right],{{\boldsymbol{{G}}}} = \left[ \begin{array}{l}\rho v\\[5pt] \rho uv\\[5pt] \rho {v^2} + p\\[5pt] \rho vw\\[5pt] \rho Hv\end{array} \right]\end{align*}

(1) \begin{align}{{\boldsymbol{{H}}}} = \left[ \begin{array}{l}\rho w\\[5pt] \rho uw\\[5pt] \rho vw\\[5pt] \rho {w^2} + p\\[5pt] \rho Hw\end{array} \right],{{{\boldsymbol{{F}}}}_{{\boldsymbol{{v}}}}} = \left[ \begin{array}{c}0\\[5pt] {\tau _{xx}}\\[5pt] {\tau _{xy}}\\[5pt] {\tau _{xz}}\\[5pt] {\tau _{xx}}u + {\tau _{xy}}v + {\tau _{xz}}w + {q_x}\end{array} \right]\end{align}
\begin{align*}{{{\boldsymbol{{G}}}}_{{\boldsymbol{{v}}}}} = \left[ \begin{array}{c}0\\[5pt] {\tau _{yx}}\\[5pt] {\tau _{yy}}\\[5pt] {\tau _{yz}}\\[5pt] {\tau _{yx}}u + {\tau _{yy}}v + {\tau _{yz}}w + {q_y}\end{array} \right]\end{align*}
\begin{align*}{{{\boldsymbol{{H}}}}_{{\boldsymbol{{v}}}}} = \left[ \begin{array}{c}0\\[5pt] {\tau _{zx}}\\[5pt] {\tau _{xy}}\\[5pt] {\tau _{zz}}\\[5pt] {\tau _{xx}}u + {\tau _{zy}}v + {\tau _{zz}}w + {q_z}\end{array} \right]\end{align*}

where p is pressure, $\rho$ is density, (u, v, w) are the Cartesian velocity components, E is total specific energy, H is total specific enthalpy, H = E + p/ $\rho$ , Q is the conserved variable, F , G , H are the convective terms, F v , G v and H v are the viscous terms.

3.2 Discrete scheme and solution method

The discrete scheme used in this study is Roe-FDS. The spatial discrete scheme is the second order upwind. The solution method is to adopt the density-based solution, velocity component and density are taken as basic variables, and the pressure is obtained by state equation. The density based solution is solved by coupling algorithm. The continuity equation, momentum equation and energy equation are solved simultaneously, and then other scalar equations are solved sequentially.

3.3 Turbulence model

Spalart-Allmaras (S-A) turbulence model is a simple single equation model for a modified turbulent kinematic viscosity [Reference Spalart and Allmaras25]. It is specially designed for aerospace applications. And it has a good application in the calculation of missile external flow field [Reference Meng, Yan, Huang and Tong26]. Compared with the two-equation model, it has lower encryption requirements for the computing grid on the wall. And it has the advantage of good stability. Previous studies [Reference Render, Samaad-Suhaeb, Yang and Mani27] on battle-damaged aerofoils had shown this model produced reasonable result, and outperformed the k- $\varepsilon$ model slightly. The transport equation of the Spalart-Allmaras model is adopted as the governing equation, and its form can be obtained from the Refs [Reference Jinbum and Seungsoo28, Reference Spalart and Allmaras29].

3.4 Boundary and initial conditions

Pressure-far-field condition is adopted at the entrance and radial boundary of the computational domain. Pressure-out condition is adopted at the outlet, the temperature and pressure are the same as the far-field. The surface of missile adopts non-slip solid wall boundary condition. The initial value of the computational flow field is set as the free flow value. The fluid types in the computational domain is ideal gas, and the viscosity is calculated using Sutherland’s law.

3.5 Dynamic derivative identification method

Forced motion offers a good alternative to predict the aerodynamic coefficients of an aircraft [Reference Allen and Ghoreyshi30]. The classic method for calculating dynamic derivatives is the small amplitude oscillation technique. It evolved from the wind tunnel tests and can calculate subsonic, transonic and supersonic states [Reference Wu, Lv and Cao31]. The Fourier expansion of unsteady aerodynamic moment on rigid aircraft with small amplitude forced pitch vibration is given as follows:

(2) \begin{align}{M_z} = {M_{{z_0}}} + {\bar M_z}\sin\!(\omega t + \lambda ) + u(t)\end{align}

According to the concept of aerodynamic derivative, the unsteady aerodynamic moment of the rigid aircraft with small amplitude forced pitch vibration can be expressed by Taylor expansion as follows:

(3) \begin{align}{M_Z} = {M_{{z_0}}} + M_z^\alpha {{\Delta }}\alpha + M_z^{\dot \alpha }{{\Delta }}\dot \alpha + M_z^{{\omega _z}}{\omega _z} + M_z^{{{\dot \omega }_z}}{\dot \omega _z} + {{\hat{\Delta} }}\left( {{{\Delta }}\alpha, {\omega _z}} \right)\end{align}

Where, $\;{{{M}}_{{z}}}$ is the transient unsteady aerodynamic moment; ${{{M}}_{{{{z}}_{{0}}}}}$ is the aerodynamic moment at the equilibrium position. ${{M}}_{{z}}^{{\alpha }}$ is the static derivative of aerodynamic moment; ${{M}}_{{z}}^{{{\dot \alpha }}}$ is the first dynamic derivative of aerodynamic moment to AoA; ${{M}}_{{z}}^{{{{\omega }}_{{z}}}}$ is the zero-order dynamic derivative of aerodynamic moment to pitch angular velocity; ${{M}}_{{z}}^{{{{{\dot \omega }}}_{{z}}}}$ is the first dynamic derivative of aerodynamic moment to pitch angular velocity; $\hat{\Delta}$ is a higher-order derivative term. When the rigid aircraft oscillates in small amplitude, its motion equation can be simplified as:

(4) \begin{align}\left\{ {\begin{array}{*{20}{l}}{\theta = {\theta _m}\sin\!(\omega t)}\\[5pt] {\dot \theta = \omega {\theta _m}\cos\!(\omega t) = {\omega _z}}\\[5pt] {\ddot \theta = - {\omega ^2}{\theta _m}\sin\!(\omega t) = {{\dot \omega }_z}}\\[5pt] {{{\Delta }}\alpha = \theta = {\theta _m}\sin\!(\omega t)}\\[5pt] {{{\Delta }}\dot \alpha = \dot \theta = \omega {\theta _m}\cos\!(\omega t)}\end{array}} \right.\end{align}

Substituting Equation (4) into Equation (3) and omitting high-order component $\hat{\Delta}$ :

(5) \begin{align}\eqalign{ & {M_Z} = (M_Z^\alpha - {\omega ^2}M_Z^{{{\dot \omega }_Z}}){\theta _m}\sin\!(\omega t) \cr & + (M_Z^{\dot \alpha } + M_Z^{{\omega _Z}})\omega {\theta _m}\cos\!(\omega t) + {M_{{Z_0}}} \cr} \end{align}

When the calculation time of the unsteady problem is long enough, the aerodynamic moment changes periodically, and the single point method can be adopted [Reference Oktay and Akay32], making ωt = 2nπ to remove the influence of the initial effect, so Equation (5) can be written as follows:

(6) \begin{align}M_z^{\dot \alpha } + M_z^{{\omega _z}} = \frac{{{{\bar M}_z}\sin \lambda }}{{\omega {\theta _m}}} = \frac{{{M_{\omega t = 2n\pi }} - {M_{{z_0}}}}}{{\omega {\theta _m}}}\end{align}

Make dimensionless treatment on the above formula. The reduced frequency is k = ωl/2V , where l is the reference length and V is the far-field free inflow velocity, substituting and obtaining:

(7) \begin{align}{C_{mq}} + {C_{m\dot \alpha }} = \frac{{{M_{\omega t = 2n\pi }} - {M_{{z_0}}}}}{{kqsl{\theta _m}}} = \frac{{{C_{{M_{\omega t}}_{ = 2n\pi }}} - {C_{{M_{{z_0}}}}}}}{{k{\theta _m}}}\end{align}

where ${{{C}}_{{{{M}}_{{{\omega t = 2n\pi }}}}}}$ is the instantaneous pitching moment coefficient at ωt = 2nπ, and ${{{C}}_{{{{M}}_{{{z0}}}}}}$ is the steady moment coefficient at the equilibrium position. k is the reduced frequency, q is the dynamic pressure, s and l are the reference area and length respectively, and ${{{\theta }}_{{m}}}$ is the amplitude.

3.6 Method validation

The Basic Finner missile model is the international standard model to validate the aerodynamic calculation. The model of the missile is shown in Fig. 4. The structural parameters are consistent with those in Ref. [Reference Bhagwandin and Sahu33], that is, d = 30mm. The computational mesh of the missile is shown in Fig. 5, and the number of grids is 2.6m. The length of the far field in the calculation domain is 10 times the length of the missile and the diameter is 20 times the diameter of the missile. The calculation conditions in this study are consistent with the Ref. [Reference Mi34], that is, Ma = 1.58, initial attack angle θ 0 = 0°, frequency reduction rate k = 0.0158226, amplitude θ m = 1°, so the oscillation law can be written as $\alpha$ = θ 0 + θ m sin(ωt) = 1°sin(571.7t).

Figure 4. Basic Finner missile model.

Figure 5. Mesh generation of Basic Finner missile.

Experimental data was obtained from a combination of free-flight tests in a ballistic range and wind tunnel measurements at different test facilities [Reference Dupuis and Hathaway35, Reference Dupuis36].

The hysteresis loops of pitch moment coefficient obtained from the calculation in this study is shown in Fig. 6. The curve basically coincides with the CFD calculation value in the Ref. [Reference Mi34], indicating that the error is small. The errors of $C_{{m}{\dot{\alpha}}} + C_{mq}$ are shown in Table 3. Error-C represents the error with the calculated value [Reference Green, Spence and Murphy37], and Error-E represents the error with the experimental value [Reference Bhagwandin and Sahu33]. Compared with the experimental and calculated values, the error of the S-A model obtained in this study is larger, but it is still less than 8%. One aspect of the analysis that contributes to this error may be due to insufficient number of grids and insufficient precision of numerical methods. On the other hand, the edge of the numerical calculation model is sharp, but the test piece usually has a certain chamfer, not a completely sharp edge, which may also cause errors between the numerical calculation and the test results. This error is acceptable, indicating that the calculation method has high reliability for calculating the aerodynamic characteristics of the missile model in this study.

Figure 6. Hysteresis loops of Cmy (Cmy represents the pitch moment coefficient).

Table 3. ${{{C}}_{{{m}{\dot \alpha }}}}{{\; + \;}}{{{C}}_{{{mq}}}}$ comparison of Basic Finner missile

4.0 Results and discussions

4.1 Static aerodynamic characteristics

First, the static aerodynamic characteristics of all models with different damage extent are simulated. The calculation conditions are listed in Table 4.

Table 4. Static calculation conditions

The differences before and after damage are analysed in terms of the flow field. Due to large number of calculation conditions and limited space, only some representative flow field contours of the damaged models are selected for display, i.e., the models with the right wing of 0.3l and 0.5l damage at $\alpha$ = 4° and $\alpha$ = 8°.

Figures 7 and 8 show the Mach and local pressure contour around the models. The oblique shock waves formed in front of the head, wings, rudders and fins of the missile can be clearly seen in the figures. The low Mach number region at the tail of the missile is also obvious. By comparison, it is found that when the AoA changes from $\alpha$ = 4° to $\alpha$ = 8°, a local high Mach number region appears behind the wing on the undamaged side (left side). On the side of the damaged wing, the region is small. When the damage extent reaches 0.5l, the above phenomenon hardly appears, which makes the flow field on both sides of the missile asymmetric.

Figure 7. Mach and local pressure contour at $\alpha$ = 4°.

Figure 8. Mach and local pressure contour at $\alpha$ = 8°.

Figures 9 and 10 show the streamlines and vortices around the models. After being damaged, the flow field asymmetry becomes larger on both sides of the missile. This asymmetry is more obvious when the AoA increases. The vortices on both sides of the missile differs significantly. The vortices formed by the damaged wing are longer but smaller in diameter compared to the undamaged left side. The streamlines show that the vortices on the damaged side become more concentrated. Compared with the left wings, the vortices formed by the right wings of the two damaged models are closer to the body of the missile and extend to the rear side of the fin at $\alpha$ = 8°, which affects the flow field around the rudders and fins behind the wings.

Figure 9. Streamlines and vortices at $\alpha$ = 4°.

Figure 10. Streamlines and vortices at $\alpha$ = 8°.

To further explore the effect of wing damage on the flow field around the missile, the pressure distribution around the wings, rudders and fins of the missile are shown separately to compare their differences (the missile body is hidden for better visibility). Due to the limitation of space, the representative pressure contour distribution at $\alpha$ = 8° is selected for display. As shown in Fig. 11, the wingtip vortices of the damaged wings are smaller than that of the undamaged wing and appear mainly in part of the wing parallel to the body. However, the pressure distribution at the leading edge of the wing is almost unaffected by the damage. As the damage extent increases, the wingtip vortices become smaller and the pressure gradient changes more drastically. This leads to a decrease in the lift coefficient and a non-linear relationship with the damage extent at the same AoA. The wingtip vortices effect of damaged models is weakened, leading to reduction in lift force along with a reduction in lift-induced drag force.

Figure 11. Pressure contour around wings at $\alpha$ = 8°.

Figures 12 and 13 show that the damaged wing also affects the flow field around the rudders and fins at the rear of the body. Due to the partial loss of right wing, the airflow through the right side of the missile body is faster and the pressure is lower, and a local low pressure region is formed between the upper and lower rudders and fins on the right side. The pressure distribution on the right rudders and fins, especially on the right upper rudder and the fin surface, produces more obvious changes, this is, the pressure distribution on the upper and lower surfaces is not symmetrical. The increased damage extent also has a great influence on the flow field around the rudder and fin at the right upper position. As a result, a counterclockwise roll moment is generated by the rudders and fins of the missile, respectively, to counteract the clockwise roll moment that occurs due to the partial missing of the right wing.

Figure 12. Pressure contour around rudders at $\alpha$ = 8°.

Figure 13. Pressure contour around fins at $\alpha$ = 8°.

Figure 14 shows the static aerodynamic force and moment coefficient. Compared to the undamaged model, both the drag and lift coefficient of the damaged model are smaller due to the loss of both windward and lift surfaces. With the increase of damage extent, both C d and C l are sensitive to the change with AoA. The rate of change is listed in Tables 5 and 6. The change rate of the drag coefficient increases with increasing damage extent as well as with increasing AoA, while the change rate of the lift coefficient increases with increasing damage extent and decreases with increasing AoA. Meanwhile, Table 6 also shows the nonlinear relationship between the reduction of lift coefficient and the damaged extent at the same AoA.

Figure 14. Static aerodynamic forces and moments.

Table 5. Cd change at different AoA

Table 6. Cl change at different AoA

The pitch moment C my of the missile is negative, which indicates that it can restrain the pitch motion and the missile is statically stable. The figure shows that as the AoA increases, the pitch moment values of several damaged models still basically obey linear changes. The more the missile wing is damaged, the larger the static pitch moment is, but the absolute value is decreasing, and the suppression of pitch motion decreases. That is, the static stability of the missile becomes worse. Due to the front of the missile wing is triangular, the surface area decreases more behind the MRP than in the front when the missile loses partial right wing.

The roll moment C mx of the undamaged model is nearly 0 at all the angles of attack. As the area loss on the right wing increases, the absolute value of the roll moment increases and gradually changes from linear to non-nonlinear. This is due to the missing lifting surface area of the missile’s right wing is not linearly related to the missing wingspan.

4.2 Dynamic aerodynamic characteristics

Based on the static solutions, dynamic grid method is used to simulate unsteady small amplitude forced vibration to calculate dynamic aerodynamic parameters. The pitch motion is defined as $\alpha$ = θ 0 + θ m sin(ωt) = θ 0 + 0.25° sin(823.2t), and the corresponding reduced frequency is k = ωl/2V = 0.24. The roll motion is defined as $\alpha$ = θ 0 + θ m sin(ωt) = θ 0 + 0.25° sin(343t), and the corresponding k is 0.1. Other parameters are the same as those in the static calculation.

Due to the unsteady flow involved, the independence of the time step must be validated before the dynamic characteristics calculation. The time step t y = 1×10−5s, 2×10-5s and 4×10-5s are used to calculate the pitch moment coefficient of the undamaged model at $\alpha$ = 0°. And the time step t x = 1×10-4s, 5×10-5s and 2.5×10-5s are used to calculate the roll moment coefficient of the undamaged model at $\alpha$ = 0°. The results in the Fig. 15 show that there is almost no difference in the calculation results. Considering the calculation time cost and calculation accuracy, the time step for calculating the pitch motion is t y = 2×10-5s, and the time step for calculating the roll motion is t x = 5×10-5s in this study.

Figure 15. Validation of moment coefficient with time during pith/roll motion (time step independence validation).

4.2.1 Pitch dynamic derivative

The hysteresis loops of the pitch moment coefficient are presented in Fig. 16. The hysteresis loops is obviously elliptical in shape, and the angle between its major axis and the x-axis is defined as the azimuth, as shown in Fig. 17. The circumferential direction of all curves is counterclockwise, which indicates the missile obtained damping characteristics of pitch moment at all attack angles. Although the different extents of the missing right wing parts, the azimuths and sizes of the hysteresis loops hardly change at the same AoA, only causing different areas of the hysteresis loops: the hysteresis loops area increases slightly with increasing of the damage extent.

Figure 16. Hysteresis loops of pitch moment coefficient at different AoA.

Figure 17. Diagram of the azimuth.

Comparing the hysteresis loops at different AoA, the azimuths change. The azimuths of $\alpha$ = 4° are opposite to that of $\alpha$ = 8° and $\alpha$ = 12°. Under the condition of the $\alpha$ = 4° and the same absolute value of oscillation instantaneous AoA, the longitudinal damping value of positive instantaneous AoA is larger than that of the negative instantaneous AoA. On the contrary, the longitudinal damping value at the negative instantaneous AoA is larger than that at the positive instantaneous AoA under the condition of $\alpha$ = 8°. The results of $\alpha$ = 12° is the same as that of $\alpha$ = 8°.

The pitch combined dynamic derivatives are shown in Fig. 18. With the increase of the AoA, the pitch combined dynamic derivatives ${{{C}}_{{{m}{\dot \alpha }}}}{{\; + \;}}{{{C}}_{{{mq}}}}$ of the damaged model and the undamaged models all increase at first and then decrease. This phenomenon is consistent with the changing trend of azimuth with the AoA mentioned earlier. However, the specific change of ${{{C}}_{{{m}{\dot \alpha }}}}{{\; + \;}}{{{C}}_{{{mq}}}}$ among individual damage models is different. At $\alpha$ = 0°, the values of ${{{C}}_{{{m}{\dot \alpha }}}}{{\; + \;}}{{{C}}_{{{mq}}}}$ decrease with the increase of damage extent. At $\alpha$ = 4°, the values of ${{{C}}_{{{m}{\dot \alpha }}}}{{\; + \;}}{{{C}}_{{{mq}}}}$ are basically the same for different damage extent. When AoA is $\alpha$ = 8°, the ${{{C}}_{{{m}{\dot \alpha }}}}{{\; + \;}}{{{C}}_{{{mq}}}}$ of the damaged model becomes larger than that of the undamaged model, and this phenomenon is more obvious at $\alpha$ = 12°. The combined dynamic derivative calculation indicates that the differences among damaged and undamaged models are mainly caused by the different missing areas of effective lifting surface before and after the moment reference point.

Figure 18. Combined dynamic derivative of pitch moment.

With the increase of AoA, the absolute values of the pitch combined dynamic derivatives first increases and then decreases with the increase of damage extent, which indicates the pitch damping characteristics don’t get worse in all cases, even slightly increase at small AoA. For the missile in this study, the dynamic performance is the worst at $\alpha$ = 4°. Compared with the undamaged model, the dynamic performance of the damaged models is even better when the AoA is within 5°. However, when the AoA exceeds 5°, it becomes worse rapidly. Generally speaking, at small angles of attack, the damage to one side of wing has little effect on the pitch dynamic performance of the missile.

4.2.2 Roll dynamic derivative

The hysteresis loops of the roll moment coefficient are presented in Fig. 19. After the wings being damaged, the hysteresis loop areas of their roll moment coefficients decrease, and the greater the damage extent, the smaller the hysteresis loops area, which is obvious at $\alpha$ = 0°. Different from the pitch direction, damage causes a great influence on the dynamic performances in the roll direction. The roll combined dynamic derivatives ${{{C}}_{{{mx\dot \alpha }}}}{{\; + \;}}{{{C}}_{{{mxq}}}}$ of several models at different AoA are shown in Fig. 20. For all models, the absolute values of the roll combined dynamic derivatives first decrease and then increase with the increase of the AoA. Compared to the undamaged model, the values of dynamic derivative of damaged models decrease a lot. When the damage is 0.5l, the absolute value of roll combined dynamic derivative decreases even more than 20%. Considering that the missile has X-shaped rudders and fins, this value is quite large. And the absolute value of the roll combined dynamic derivatives first decreases and then increases with the increase of the AoA, and this trend is the same as that of pitch combined dynamic derivatives. The turning point appears between $\alpha$ = 4° and $\alpha$ = 8°. According to Fig. 18, it is guessed that it may appear around $\alpha$ = 5°. However, different from the pitch direction, the roll performance of damaged models deteriorates at all angles of attack, which is also consistent with reality.

Figure 19. Hysteresis loops of roll moment coefficient at different AoA.

Figure 20. Combined dynamic derivative of roll moment.

4.2.3 Pitch-roll coupling dynamic derivative

The unsteady roll moment coefficient is shown in Fig. 21. The pitch-roll coupling moment caused by pitch oscillation is in the same order of magnitude as the roll moment, so it cannot be neglected. At $\alpha$ = 0°, the pitch-roll moments of all models differ by several orders of magnitude from other angles of attack, and it is nearly 0, so the hysteresis loop is not shown. When AoA is more than 0°, the force on the left and right sides of the missile is unbalanced in pitch oscillation, which in turn leads to roll moment. Meanwhile, the pressure centre is away from the centre of gravity in the longitudinal and transverse directions respectively. It leads to an increase in the areas of the hysteresis loops, which makes the dynamic coupling characteristics between the pitch and roll directions increasing apparently. With the increase of the initial AoA, the azimuths of hysteresis loops also decrease, and the pitch-roll hysteresis loops tend to be horizontal when the instantaneous AoA changes.

Figure 21. Unsteady roll moment coefficient caused by the pitch oscillation.

4.3 Damage limit of missile wing

After the unilateral wing of the missile is damaged, roll dispersion results from lift non-averaging produced by body-fixed vehicle asymmetries will appear [Reference Fuess38, Reference Crenshaw39]. Some aerodynamic performances can be saved by controlling the deflection of the rudders. The damage limit of the missile wing is judged since the missile does not roll. That is, the static balance of the missile after the wing damage is maintained by four rudder deflections. The full roll moment of the missile can be expressed as:

(8) \begin{align}{C_m} = {C_{{m_0}}} + {C_m}(\alpha ) \cdot \alpha + {C_m}(\beta ) \cdot \beta \end{align}

where, C m is the full roll moment, C m0 is the zero-liter moment, C m ( $\alpha$ ) $\cdot$ $\alpha$ is the roll moment caused by the AoA $\alpha$ , and C m ( $\beta$ ) $\cdot$ $\beta$ is the trim moment caused by the rudder deflection angle $\beta$ .

Figure 22 shows the roll moment provided by one rudder at different deflection angles. In the figure, $\beta$ represents the deflection angle of a single rudder. It can be seen from the figure that with the increase of the AoA, the static roll moment provided by the smaller rudder deflection angles first increase and then decrease. The roll moments provided by the larger rudder deflection angles decrease continuously.

Figure 22. Roll moment coefficient caused by one rudder deflection.

The deflection efficiency of the remaining three rudders is regarded as the superposition of one rudder. Through this simplified processing, the roll moment provided by the four rudders at different angles of attack can be obtained. The maximum deflection angle of each rudder is limited to 15°. Figure 23 shows the static roll moments that can be provided when all four rudders are deflected to 15°, as well as the roll moment required to maintain balance for four models with different extents of damage at different angles of attack.

Figure 23. The static roll moments provided by four rudders, and the roll moments required of different damaged models.

As can be seen in Fig. 23, even at a maximum angle-of-attack of $\alpha$ = 12°, all damaged models in this study can achieve roll moment balancing. Next, the damage limit of missile wing at $\alpha$ = 12° will be studied, which is the worst flight condition. According to the relationship between the change of roll moment coefficient and the damage extent of missile wing, it is found that it basically conforms to the linear change law: C mx = −0.2941(h/l). When the four rudders are all deflected to 15°, the maximum roll moment available is C mxr = −0.1829. Then, the maximum allowable wing damage extent is h/l = 0.625 when the missile does not roll.

Finally, the correctness of the damage limit needs to be validated by numerical simulation. The results are shown in Table 7. C mxt represents the roll moment coefficient of the missile with right wing h/l = 0.625 damage trimmed by rudders deflection. The relative error C mxt /C mxr is −2.023%. This is a relatively small value. This shows that the limit damage extent of missile wing is h/l = 0.625 with high credibility.

Table 7. Trim validation of the h/l = 0.625 damaged model at $\alpha$ = 12°

5.0 Conclusions

CFD simulation are implemented on the simplified model of supersonic cruise missile, including undamaged model and four models with different damage extents of wing. The static aerodynamic force and moment of all models have been calculated and compared. On this basis, the dynamic pitch, roll and pitch-roll coupling moments are further computed. The combined dynamic derivatives are obtained and their variation rules after being damaged are found. The main conclusions are as follows:

(1) The partial missing area of the lift surface on the right wing causes geometric asymmetry, which further leads to the asymmetry of the flow field. Compared to the undamaged model, the damaged models have small drag and lift coefficients. With the increase of damage extent, both drag and lift coefficients are sensitive to the change of the AoA, but their respective rates of change are different: the change rate of drag coefficient at the larger AoA is greater than that at the smaller AoA. On the contrary, the change rate of lift coefficient at the larger AoA is smaller than that at the lower AoA. Meanwhile, the absolute value of static pitch moment decreases, and the suppression of missile pitch motion weakens. The absolute value of the roll moment increases, and gradually changes from linear to non-nonlinear.

(2) The dynamic pitch and roll performances of the missile are both the worst when the AoA is $\alpha$ = 4°. Compared with the undamaged model, the pitch performance of the damaged models is even better when the AoA is within 5°, but it becomes worse when the AoA exceeds 5°. For all models, the absolute values of the roll combined dynamic derivatives first decrease and then increase with the increase of the AoA like the tendency of the pitch direction. The turning point appears around $\alpha$ = 5°. Different from the pitch direction, the roll performance of damaged models deteriorates at all angles of attack. Relatively speaking, the influence of wing damage on the roll direction is much greater than that on the pitch direction. In addition, the extension in the loss area causes the dynamic coupling characteristic between the pitch and roll directions to increase apparently.

(3) The maximum allowable damage extent of the missile wing that can achieve static trim is obtained at $\alpha$ = 12° and the maximum deflection angle of the single rudder is 15°.When the four rudders are all deflected to 15°, the allowable damage limit of the missile wing that maintains the balance of the roll direction is h/l = 0.625. And its credibility is proved by numerical validation.

Acknowledgements

The authors would like to acknowledge the support of National Natural Science Foundation of China (Grant No. 11602109).

Competing interests

The authors declare that they have no competing interests.

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Figure 0

Figure 1. Geometric model and damage diagram.

Figure 1

Table 1. Basic parameters of missile

Figure 2

Figure 2. Mesh generation of the missile.

Figure 3

Figure 3. Mesh independence validation.

Figure 4

Table 2. Mesh independence error of Cd

Figure 5

Figure 4. Basic Finner missile model.

Figure 6

Figure 5. Mesh generation of Basic Finner missile.

Figure 7

Figure 6. Hysteresis loops of Cmy (Cmy represents the pitch moment coefficient).

Figure 8

Table 3. ${{{C}}_{{{m}{\dot \alpha }}}}{{\; + \;}}{{{C}}_{{{mq}}}}$ comparison of Basic Finner missile

Figure 9

Table 4. Static calculation conditions

Figure 10

Figure 7. Mach and local pressure contour at $\alpha$ = 4°.

Figure 11

Figure 8. Mach and local pressure contour at $\alpha$ = 8°.

Figure 12

Figure 9. Streamlines and vortices at $\alpha$ = 4°.

Figure 13

Figure 10. Streamlines and vortices at $\alpha$ = 8°.

Figure 14

Figure 11. Pressure contour around wings at $\alpha$ = 8°.

Figure 15

Figure 12. Pressure contour around rudders at $\alpha$ = 8°.

Figure 16

Figure 13. Pressure contour around fins at $\alpha$ = 8°.

Figure 17

Figure 14. Static aerodynamic forces and moments.

Figure 18

Table 5. Cd change at different AoA

Figure 19

Table 6. Cl change at different AoA

Figure 20

Figure 15. Validation of moment coefficient with time during pith/roll motion (time step independence validation).

Figure 21

Figure 16. Hysteresis loops of pitch moment coefficient at different AoA.

Figure 22

Figure 17. Diagram of the azimuth.

Figure 23

Figure 18. Combined dynamic derivative of pitch moment.

Figure 24

Figure 19. Hysteresis loops of roll moment coefficient at different AoA.

Figure 25

Figure 20. Combined dynamic derivative of roll moment.

Figure 26

Figure 21. Unsteady roll moment coefficient caused by the pitch oscillation.

Figure 27

Figure 22. Roll moment coefficient caused by one rudder deflection.

Figure 28

Figure 23. The static roll moments provided by four rudders, and the roll moments required of different damaged models.

Figure 29

Table 7. Trim validation of the h/l = 0.625 damaged model at $\alpha$ = 12°