Aerodynamic measurement of a large aircraft model in hypersonic flow

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Meng Bao-Qing, Han Gui-Lai, Zhang De-Liang, Jiang Zong-Lin. Aerodynamic measurement of a large aircraft model in hypersonic flow. Chinese Physics B, 2017, 26(11): 114702 Copy to clipboard

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Aerodynamic measurement of a large aircraft model in hypersonic flow

Meng Bao-Qing^{1, 2}, Han Gui-Lai^{1, †}, Zhang De-Liang^{1, 2}, Jiang Zong-Lin^{1, 2}

1State Key Laboratory of High-temperature Gas Dynamics, Institute of Mechanics, Chinese Academy of Sciences, Beijing 100190, China

2University of Chinese Academy of Sciences, Beijing 100049, China

† Corresponding author. E-mail: hanguilai@imech.ac.cn

Abstract

Accurate aerodynamic measurements in the hypersonic flow of large aircraft models in tunnels have practical significance, but pose a significant challenge. Novel aerodynamic force measurement methods have been proposed,but lack theoretical support. The forms of the force signals techniques for signal processing and calculation of aerodynamics are especially problematic. A theoretical study is conducted to investigate the dynamic properties based on models of the draw-rod system and slender rods. The results indicate that the inertia item can be neglected in the rod governing equation; further, the solutions show that the signals of each rod are a combination of aerodynamic signals (with a constant value) and sine signals, which can be verified by experimental shock tunnel results. Signal processing and aerodynamics calculation techniques are also found to be achievable via the flat part of the signals.

PACS: 47.40.Ki;46.40.-f;46.80.+j

Keyword:hypersonic;aerodynamic measurement;theoretical study;vibration

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1. Introduction

Accurate aerodynamic measurements in the hypersonic flow of an in-tunnel full-scale aircraft model are important,^[1] but are challenging. The measurement of a full-scale aircraft model requires a sufficiently large wind tunnel platform with excellent free stream quality and an innovative support form for the model.

The shock tunnel is an important piece of ground equipment in the aerospace research field. The current tunnel limits the size of the aircraft model,^[2,3] but can be used to provide a high total pressure and a high total temperature at relatively low cost. The traditional shock tunnel is only capable of satisfying the measurement of models several hundred millimeters in length, which renders experiments on full-scale models impossible.^[4–7] The long-test-duration hypersonic detonation-driven shock tunnel^[8] (JF12 shock tunnel) allows full-scale model measurement; the exit diameter of its nozzle is 2.5 m and the diameter of its test section is 3.5 m. It is capable of reproducing pure air flow with Mach numbers from 5–9 at altitudes of 25–50 km.

An effective support form is also crucial for aerodynamic measurements of a full-scale aircraft model in the shock tunnel. As a typical piece of impulse equipment, the running time of the shock tunnel is very short, generally between approximately 2 and 100 ms,^[4,5] which makes the accurate measurement of the aerodynamic force of any model extremely difficult. A running time of several minutes was reported for the conventional tunnel;^[9] this duration was found to be far longer than the vibration period of a force measurement structure. Further, the effects of damping were very apparent and the initial vibrations of the force measurement system were decayed. The whole structure can reach the force equilibrium state resulting in quasi-static (and thus highly accurate) measurements. In the shock tunnel, conversely, vibrations, balance, and support of the model are triggered by the impulse force due to the strong primary shock^[10–14] during nozzle start-up. The damping effects can be neglected as the order of the magnitude of the test time is identical to that of the force measurement structure period. To this effect, aerodynamic force balance usage is a dynamic measurement process.

Several periods of signals are essential for dynamic signal processing and aerodynamics calculation. Individual signals sensed by the balance form a combination of signals corresponding to the aerodynamic force and vibration. Removal of the vibrational signals represents an essential and critical step processing force signals in the shock tunnel. Several periods (typically more than three) of signals should be tested to ensure accuracy. However, the natural frequencies of a measurement system rely heavily on the support form. More periods of signals would enhance the accuracy of peeled-off vibrational signals.^[15,16] Thus, the support form of the model largely determines the overall accuracy of force measurements.

Rear sting supports are the most commonly used support forms in shock tunnels.^[17–25] However, the cantilever-beam type limits the frequency, so the mass of the model is limited to a few hundred grams and the length magnitude within the millimeter level. The mass of a full-scale aircraft model is close to 1000 kg. The vibrational frequencies markedly decrease as the model mass increases in these setups. The equation of the frequency for the spring-vibrator model suggests that , that is the frequency decreases by two orders of the magnitude as the mass varies from 100 grams to 1000 kg. Side support is another commonly used method,^[26] which can supply sufficient stiffness in the axial direction, which is typically applied to measure the engine thrust. Again, with increasing model mass (particularly for a full-scale aircraft model with an integrated engine), the side support introduces poor stiffness in both side and normal directions.

Researchers have recently developed a novel aerodynamic force measurement method for large aircraft models in the JF12 shock tunnel.^[25] The applicable model mass is about 300–1000 kg and its length is about 3–5 m. The aircraft model used to explore this method was hung via the draw-rod system (Fig. 1), which includes several slender rods (typically more than six) connected to the model at different positions. Force transducers were linked to both the rods and the rigid base around the wall of the test section. In contrast to the single-surface support form of the rear sting support, the draw-rod system provides multipoint support and superior frequency performance.

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	Fig. 1. (color online) (a) Force analysis prior to tunnel testing. (b) Force analysis during testing.

The preliminary study on this novel aerodynamic measurement method merits some further clarification. The forms of the force signals, for example, are unclear. Effective removal of vibrational signals depends heavily on the signal forms, which are closely related to the overall feasibility and the accuracy of the method. The technique for obtaining the aerodynamics from the force signals should also be further explored. Theoretical support still has these two essential problems. In this study, the theory of static force vectors was investigated in this regard as a series of basic dynamic measurement concepts. Further assessment under the structural dynamics theory was also conducted to investigate the working process of the draw-rod system in the shock tunnel. A few relevant theoretical solutions were proposed, as discussed below.

2. Superposition of forces and moments

The superposition of forces and moments is based on the principle of equilibrium within three dimensional force systems i.e., the static theory. It is generally applied in low-speed tunnels with a wire-support system.^[27,28] In this study, we also found that it is related to the dynamic aerodynamic measurements.

Before testing the tunnel, the resultant forces and gravity of the model were considered to be in equilibrium as shown in Fig. 1(a) and expressed in Eq. (1). is the gravity vector and is the inner force vector of each rod. is the position vector from the original point to the acting position of gravity. is the position vector from the original point to the acting position of the inner force of each rod. During testing, the forces on each rod change and the resulting forces, gravity and aerodynamic forces are in equilibrium as shown in Fig. 1(b) and expressed in Eq. (2). and are the aerodynamic drag and lift of the aircraft model respectively, is the aerodynamic moment of the aircraft model during the tunnel test. 1a 1b 2a 2b Equations (1) and (2) express the aerodynamic forces and moments and combine to form Eq. (3). is the variation of the force for each rod which can be output by force transducers via a data acquisition instrument is the direction vector of the corresponding rod, which can be extracted via the coordinate system 3a 3b

3. Investigation of dynamic measurement

The aerodynamic force measurements in the shock tunnel are a dynamic process. Thus, the force measurement theory of the draw-rod system in a shock tunnel is characterized by structural dynamics. The dynamic properties of the aircraft model and rods can be investigated separately. The ultimate objective of applying dynamic theory is to obtain the aerodynamic force with the measured signals of each rod.

The vibration of the whole system can be roughly divided into two stages corresponding to the test process: the forced impulse stage and the steady vibration stage.Signals can be efficiently acquired during steady vibration of the draw-rod system. The following basic assumptions were applied:

The vibration of the whole system can be simplified as a multidegree-of-freedom structure as describedby^[29] 4 is the mass matrix of the system and it is composed of the model mass and inertia moments 5 is the displacement vector of the aircraft model 6 is the stiffness matrix^[30] of the whole system 7a 7b 7c 7d l_r, m_r, n_r are the direction cosines of each rod. x_r, y_r, z_r are the coordinates of the connecting positions of each rod. is the orientation matrix; it is related solely to the orientations of the rods. is the action point matrix, which is comprised solely of the connecting points of each rod and the aircraft model.

3.1. Theoretical solutions

The natural frequencies were determined via the properties of the force measurement structure, which can be solved via the following free vibration equation: 8 Assuming that 9 and substituting Eq. (9) into Eq. (8) 10 11 Let the determinant of the coefficient matrix be zero; the eigenvalues ω_i of the matrix are natural frequencies. The characteristic vectors consist of the modal matrix .

Let act on Eq. (4) by left multiplication; then the regular coordinate transformation is applied in Eq. (12) 12 so that the forced vibration equation can be written as follows: 13 The following also holds: 14a 14b 14c where is the generalized force vector. and are the generalized mass matrix and the stiffness matrix, respectively. Both and are diagonal matrices, so equation (13) can be decoupled as follows: 15 The decoupled form of Eq. (15) for generalized displacements can be written as follows: 16 17 The solution of Eq. (16) is given by 18 For the actual condition in the shock tunnel, the form of is a step load with the amplitude denoted as F_i 19 The displacement vector of model can be solved via Eqs. (12) and (19).

3.2. Order analysis and rodsignals

The rods used in the tests are uniform and have equal cross sections. The dynamic process belongs to one-dimensional and longitudinal vibration and can be expressed as follows:^[29] 20 The symbol u(xt) is the axial displacement and x is the axial direction of the rod. Symbol t denotes the physical time and A is the cross-sectional area of the rod. E is the elasticity modulus of the rod and P₀ is its exciting force. The term corresponds to the inertia force of the unit length corresponds to the unit length inertia force, and is the outer excitation force.

Natural frequencies:^[29] 21a

Normal modes: 21b

Generalized force: 21c

Normal coordinate: 21d

Displacement solution: 21e Based on Eqs. (21a)–(21e), the detailed form of is given by 21f

The magnitude analysis was conducted for each term in Eq. (20). The orders or the values of each term were evaluated according to the results of the previous tests. Generally, the sum of the first ten modes is sufficient to replace the whole vibration. 22a 22b 22c 22d 22e Per Eqs. (22a)–(22e), the displacement of the origin is 23 The extension length of each rod is close to the displacement of connecting the position of the rods and aircraft model and is expressed as follows: 24 The characteristic time equal to the vibrational period is 25 The order of the acceleration is 26 The order of the inertia force is 27 The ratio of the inertia force and the outer excitation force is 28 Thus, the inertial force of the rods can be neglected because it is much smaller than the outer excitation forces. Equation (21) can be simplified as follows: 29 The extension lengths can be calculated from the displacement vector 30 The inner forces of each rod are 31 and the composition of N_r is 32a 32b The inner force N_r is a combination of a constant value (flat signals) and some sine functions as per the detailed form of given in Eq. (19), so the form of the signals of each rod has been identified.

3.3. Methods of dynamic signals processing

Signal processing is a crucial issue^[19–21] inherent to the force measurement in shock tunnels. The signal compositions for each rod in the draw-rod system were determined as described above; the methods of dynamic signals in rod processing were then established to calculate the aerodynamics.

The sinusoidal signals can be removed via signal processing (e.g., the LDSE method). The generalized displacement given in Eq. (19) is a constant (independent of time), as indicated by Eq. (33). The relationship between the displacement and the generalized displacement is shown in Eq. (34). It should be noted that and are independent of t. 33a 33b 34 The extension length form of each rod corresponding to the processed signals is similarly given in Eq. (35). The internal force of each rod can be obtained as 35 36 The resulting force can be written as follows: 37 Further, 38

Thus, the method to obtain the aerodynamics is complete. Each experimental signal contains a flat signal and some sine signals. Numerical methods such as LDSE, as mentioned above, can be applied to extract sine signals as vibrational signals. The frequencies of sine signals are equal to the natural frequencies of the structure. The remaining parts of signals are the flat signals which correspond to a constant force as the inner forces of the rods. The superposition of forces and moments can then be applied, where the constant forces of each rod are similar to the static force in Eqs. (3a) and (3b). The resultant value obtained in Eqs. (3a) and (3b) equals the excitation force, i.e., the aerodynamic force.

3.4. Verification by shock tunnelexperiments

The signals of the inner forces are a combination of a constant value (flat signals) and some sine signals. Figure 2(a) presents the signals measured by experiments in a shock tunnel. The signals numbered CH9 and CH10 represent the inner forces of the rods along the axial direction. The signal compositionswere analyzed by LDSE.^[15,16] The compositions of signals CH9 contain flat signals (with an average value of about 1.2) and two sinusoidal signals with frequencies of 23.8 Hz and 80.2 Hz, as shown in Fig. 2(b). These signal compositions validate the theoretical predictions provided above.

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	Fig. 2. (color online) (a) Experimental signals of the rods at tail; (b) compositions of CH9 signals (corresponding to the rod at tail).

The theory that sine signal frequencies equal the natural frequencies of the structure was also validated by experiments. The natural frequencies were measured by knocking experiments. The signals were acquired by accelerometers. The Fourier analysis was applied to measure the natural frequencies. Figure 3 presents the signals of accelerometers along the axial direction with a frequency of 26 Hz. The compositional analysis suggests that 23.8 Hz is the main frequency of the inner force signals, which is very close to 26 Hz. The differences in the frequency values may be due to the signal range selected for LDSE and the position differences of the accelerometers and a force transducer.

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	Fig. 3. Signals of accelerometers in the axial directions and Fourier analysis.

4. Conclusion

In this study, theoretical support was established for a novel aerodynamic force measurement method applicable to large aircraft models for JF12 shock tunnel tests. The draw-rod system and slender rods were modeled and verified numerically.

A physical model was set up for the draw-rod system, and its dynamic properties were analyzed via structural dynamics. A detailed order analysis was also conducted to simplify the vibrational equation of the rods. We found that the inertia force of the rods is much smaller than the outer excitation force. The signals of each rod were identified as a combination of a constant value (flat signal) and sine signals. The experimental results also support this theoretical conclusion.

A method for signal processing and aerodynamics calculation was also proposed here, in which each experimental signal contains a flat signal and some sinusoidal signals. The sine signal frequencies are equal to the natural frequencies of the structure. Vibrational signals can be removed; the remainders are flat signals, which can be converted to a constant force as the inner forces of the rods. The resultant inner constant forces based on the superposition of forces and moments are equal to the aerodynamic forces. These theoretical predictions were validated by experimental tests in an actual shock tunnel.

In the future, we plan to further investigate the interference induced by the rods on aerodynamic measurements.

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