2.1 Separation mechanism design principle

The separation mechanism plays a pivotal role in enabling the combined aircraft to execute mission arrangements. A stable separation process is paramount as it ensures favourable initial flight conditions for the air vehicle. As depicted in Fig. 1, we have designed a separation mechanism that is installed in the wing tip of the combined aircraft. This configuration allows for swift and autonomous flight of the air vehicle following separation, offering enhanced convenience. The driving system is installed in the body wing and the separation system is installed in the single wing.

Figure 1. Layout of unlocking and separating mechanism.

In conventional separation mechanisms, both pyrotechnic devices and electromagnetic devices often result in instantaneous impact during the separation process. However, in this study, we have implemented a novel approach by employing a sine function as the design curve for the spiral chute in the separation mechanism. By doing so, we aimed to ensure that the single wing exhibits exceptional low-impact characteristics during separation. The curve-function is shown as follows.

(1) \begin{align} s = h\left[ {\frac{\delta }{{{\delta _0}}} - \frac{{\rm{1}}}{{{\rm{2\pi }}}}{\rm{sin}}\left( {\frac{{{\rm{2\pi }}}}{{{\delta _0}}}\delta } \right)} \right] \end{align}

2.2 Separation mechanism working principle

Before separation, the sliding pin is positioned at the bottom of the spiral chute, as depicted in Fig. 2. This restricts the movement of the flange in the shaft direction. Additionally, the three set pins align with the three pin holes in the body wing, which restricts the remaining five degrees of freedom of the individual wing. Consequently, the two wings are interlocked in a rigid connection. During the separation process, the synchronous driving system propels the sliding pins to glide within the spiral chute. This action pushes the flange in an outward direction. Simultaneously, the set pins slide out of the pin holes, enabling the two wings to complete the separation procedure. Due to the sinusoidal function curve design of the spiral chute trajectory, the separation speed and acceleration of the individual wing exhibit a compliant characteristic throughout the separation process. This compliant behaviour eliminates any impact load, thus ensuring the stability of the separation process.

Figure 2. The working principle of the unlocking separation mechanism: (a) the state of the body wing and single wing before and after separation; (b) the process of rotary separation of the separation mechanism.

3.1 Aerodynamic model of single wing

The standard rigid-body dynamic model [Reference Etkin21] is adapted with the addition of forces and moments due to linked aircrafts. The translational and rotational kinematic equations of a fixed-wing aircraft are given by:

(2) \begin{align}\dot{\boldsymbol{r}} = \boldsymbol{R}_B^I\left[ \begin{array}{l}u\\v\\w\end{array} \right]\end{align}

(3) \begin{align}\left[\begin{array}{c} {\dot \phi } \\[3pt] {\dot \theta } \\[3pt] {\dot \psi } \end{array} \right] = \left[ \begin{array}{c@{\quad}c@{\quad}c} 1 & {{s_\phi }{t_\theta }} & {{c_\phi }{t_\theta }} \\[3pt] 0 & {{c_\phi }} & { - {s_\phi }}\\[3pt] 0 & {s_\phi }/{c_\theta} & {c_\phi }/{c_\theta }\end{array} \right]\omega \end{align}

(4) \begin{align} \boldsymbol{R}_B^I = \left[ {\begin{array}{c@{\quad}c@{\quad}c}{{c_\theta }{c_\psi }} & {{s_\phi }{s_\theta }{c_\psi } - {c_\phi }{s_\psi }} & {{c_\phi }{s_\theta }{c_\psi } + {s_\phi }{s_\psi }}\\[3pt]{{c_\theta }{s_\psi }} & {{s_\phi }{s_\theta }{s_\psi } + {c_\phi }{c_\psi }} & {{c_\phi }{s_\theta }{s_\psi } - {s_\phi }{c_\psi }}\\[3pt]{ - {s_\theta }} & {{s_\phi }{c_\theta }} & {{c_\phi }{c_\theta }}\end{array}} \right]\end{align}

The vehicle dynamic equations are given by:

(5) \begin{align}\left[ \begin{array}{l}{\dot u}\\[2pt]{\dot v}\\[2pt]{\dot w}\end{array} \right] = \frac{1}{m}\left[ {{\boldsymbol{F}_{\rm{A}}} + m\boldsymbol{R}_I^B\left[ \begin{array}{l}0\\[2pt]0\\[2pt]g\end{array} \right] + {\boldsymbol{F}_{\rm{T}}} + {\boldsymbol{F}_{\rm{L}}}} \right] - \omega \times \left[ \begin{array}{l}u\\[2pt]v\\[2pt]w\end{array} \right]\end{align}

(6) \begin{align}\dot{\boldsymbol\omega} = {\boldsymbol{J}^{ - 1}}\left[ {{\boldsymbol{M}_{\rm{A}}} + {\boldsymbol{M}_L} - \omega \times \left( {\boldsymbol{J}\boldsymbol\omega } \right)} \right]\end{align}

The aerodynamic forces and moments are given by:

(7) \begin{align}{\boldsymbol{F}_{\rm{A}}} = \bar qS\left[ {\begin{array}{c@{\quad}c@{\quad}c}{ - {c_\alpha }}& 0& {{s_\alpha }}\\[3pt]0& {\rm{1}}& 0\\[3pt]{ - {s_\alpha }}& 0& { - {c_\alpha }}\end{array}} \right]\left[ \begin{array}{l}{C_{\rm{D}}}\\[3pt]{C_{\rm{Y}}}\\[3pt]{C_{\rm{L}}}\end{array} \right]\end{align}

(8) \begin{align}{M_{\rm{A}}} = \bar qS\left[ {\begin{array}{c@{\quad}c@{\quad}c}b & 0 & 0\\[3pt]0 &{\bar c} &0\\[3pt]0 & 0 & b\end{array}} \right]\left[ \begin{array}{l}{C_{\rm{l}}}\\[3pt]{C_{\rm{m}}}\\[3pt]{C_{\rm{n}}}\end{array} \right]\end{align}

The aerodynamic coefficients are obtained using the generic nonlinear aerodynamic model found in [Reference Grauer and Morelli22, Reference Grauer and Morelli23].

3.2 Friction model of set pin

During the separation process, the frictional force generated by the set pin and pin hole will prevent the single wing from moving outward at this time. Let the number of set pins on the single wing be n, O_x is the position of a set pin on the separation surface. Figure 4 depicts the force state of the set pin and the pin hole.

Figure 4. Force analysis of set pin and pin hole.

The total friction force in the single wing’s centroid coordinate system o_cx_cy_cz_c as follows:

(9) \begin{align}{\boldsymbol{F}_{\rm{f}}} = \left\{ {\begin{array}{c}{ - \sum\limits_{i = {\rm{1}}}^n {{F_{{\rm{f}}i}}} }\\[6pt]0\\[3pt]0\end{array}} \right\}\end{align}

In the separation process, the torque generated by the set pin is shown as follows:

(10) \begin{align}{\boldsymbol{M}_{\rm{f}}} = {\boldsymbol{M}_{{\rm{f1}}}} + {\boldsymbol{M}_{{\rm{f2}}}}\end{align}

The torque caused by the set pin friction on the monomer centroid is shown as follows:

(11) \begin{align}{\boldsymbol{M}_{{\rm{f1}}}} = {\boldsymbol{r}_{{\rm{ox}}}} \times {\boldsymbol{F}_{\rm{f}}}\end{align}

(12) \begin{align}{\boldsymbol{r}_{{\rm{ox}}}} = \left\{ {\begin{array}{*{20}{c}}{{x_{{\rm{ocx}}}}}\\{{y_{{\rm{ocx}}}}}\\{{z_{{\rm{ocx}}}}}\end{array}} \right\} = \left\{ {\begin{array}{*{20}{c}}{{x_{{\rm{ox}}}} - {x_{{\rm{co}}}}}\\{{y_{{\rm{ox}}}} - {y_{{\rm{co}}}}}\\{{z_{{\rm{ox}}}} - {z_{{\rm{co}}}}}\end{array}} \right\}\end{align}

The balance equation between the external torque generated by the single wing aerodynamic force and the internal torque of the set pin is shown as follows:

(13) \begin{align}{\boldsymbol{M}_{\rm{A}}} + {\boldsymbol{M}_{{\rm{f1}}}} + {\boldsymbol{M}_{{\rm{f2}}}} = 0\end{align}

(14) \begin{align}{\boldsymbol{M}_{\rm{A}}} = \left\{ \begin{array}{l}{M_{{\rm{xc}}}}\\[4pt]{M_{{\rm{yc}}}}\\[4pt]{M_{{\rm{zc}}}}\end{array} \right\}\end{align}

Since the set pin has no torque in the yz plane, friction produces an internal torque as shown as follows:

(15) \begin{align}{\boldsymbol{M}_{{\rm{f2}}}} = \left\{ {\begin{array}{c}0\\[3pt]{{M_{{\rm{f2y}}}}}\\[3pt]{{M_{{\rm{f2z}}}}}\end{array}} \right\} = \left\{ {\begin{array}{c}0\\[5pt]{ - {M_{{\rm{yc}}}} + \sum\limits_{i = {\rm{1}}}^n {{z_{{\rm{ox}}i}}{F_{{\rm{f}}i}}} }\\[7pt]{ - {M_{{\rm{zc}}}} - \sum\limits_{i = {\rm{1}}}^n {\left( {{y_{{\rm{ox}}i}} - {y_{{\rm{co}}}}} \right){F_{{\rm{f}}i}}} }\end{array}} \right\}\end{align}

According to Coulomb’s law of friction, the friction force on any set pin is shown as follows:

(16) \begin{align}{F_{{\rm{f}}i}} = {f_{\rm{d}}} \cdot \left( {{\rm{2}}{F_{\rm{N}}}} \right)\end{align}

The results obtained by substituting in Equation (15) are as follows:

(17) \begin{align}{\boldsymbol{M}_{{\rm{f2}}}} = \left\{ {\begin{array}{*{20}{c}}0\\[4pt]{ - {M_{{\rm{yc}}}} + \sum\limits_{i = {\rm{1}}}^n {{z_{{\rm{ox}}i}}{f_{\rm{d}}} \cdot \left( {{\rm{2}}{F_{\rm{N}}}} \right)} }\\[6pt]{ - {M_{{\rm{zc}}}} - \sum\limits_{i = {\rm{1}}}^n {\left( {{y_{{\rm{ox}}i}} - {y_{{\rm{co}}}}} \right){f_{\rm{d}}} \cdot \left( {{\rm{2}}{F_{\rm{N}}}} \right)} }\end{array}} \right\}\end{align}

Assuming that each set of set pins provides the same internal torque, the internal torque of n set pins is shown as follows:

(18) \begin{align}{M_{{\rm{f2}}}} = n \cdot {F_{\rm{N}}} \cdot {\delta _{\rm{L}}}\end{align}

Equations (17) and (18) are identical in value, and the necessary conditions for the existence of positive pressure of set pin can be obtained as follows:

(19) \begin{align} n \cdot {\delta _{\rm{L}}} \gt 2 {f_{\rm{d}}}\sqrt {{{\left( {\sum\limits_i {{z_{{\rm{ox}}i}}} } \right)}^{\rm{2}}} + {{\left( {\sum\limits_i {{y_{{\rm{ox}}i}}} } \right)}^{\rm{2}}}} \end{align}

At the same time, the necessary conditions for the separation of a single wing are as follows:

(20) \begin{align} {F_{\rm{f}}} \lt {F_{\rm{T}}}\end{align}

3.3 The relationship between unlocking torque and friction

Figure 5 depicts the mechanical model of the separating mechanism. Figure 5a displays the stress state of the rotating pin at any given time, and Fig. 5b depicts the stress state of the unlocking and flange at the same time.

Figure 5. Force analysis model of unlocking and separating mechanism: (a) force analysis of sliding pin; and (b) force analysis of unlocking flange.

The force equation of the sliding pin is as follows:

(21) \begin{align}\left\{ \begin{array}{l}{\boldsymbol{F}_{{\rm{xx}}}} = {\boldsymbol{F}_{{\rm{xx}}}}^{{\rm{fix}}} - {\boldsymbol{F}_{{\rm{xN}}}}{\rm{sin}}\theta - {\boldsymbol{F}_{{\rm{x}}f}}{\rm{cos}}\theta \\[4pt]{\boldsymbol{F}_{{\rm{xy}}}} = {\boldsymbol{F}_{{\rm{xy}}}}^{{\rm{fix}}} + {\boldsymbol{F}_{{\rm{xN}}}}{\rm{cos}}\theta - {\boldsymbol{F}_{{\rm{x}}f}}{\rm{sin}}\theta \\[4pt]{\boldsymbol{M}_{{\rm{xo}}}} = \boldsymbol{M}_{{\rm{xo}}}^{{\rm{fix}}} - {\boldsymbol{F}_{{\rm{x}}f}} \cdot r\end{array} \right.\end{align}

Based on the actual motion of the sliding pin, the unlocking conditions are as follows:

(22) \begin{align}\left\{ \begin{array}{l} {\boldsymbol{F}_{{\rm{xx}}}} = {\dfrac{{\boldsymbol{M}_0}}{{\rm{2}}{l_0}}}{\rm{ \gt 0}} \\[6pt] {\boldsymbol{F}_{{\rm{xy}}}} = 0 \\[4pt] {\boldsymbol{M}_{{\rm{xo}}}} = 0 \end{array} \right.\end{align}

The unlocking torque is provided by the sliding pin support in Fig. 2.

(23) \begin{align}{M_{\rm{T}}} = {\rm{2}} \cdot \left| {{F_{{\rm{xx}}}}^{{\rm{fix}}}} \right| \cdot {\rm{R}}\end{align}

The force equation of the flange under the rotation of the sliding pin is as follows:

(24) \begin{align}\left\{ \begin{array}{l}{\boldsymbol{F}_{{\rm{px}}}} = {\boldsymbol{F}_{{\rm{px}}}}^{{\rm{fix}}} + {\boldsymbol{F}_{{\rm{pN}}}}{\rm{sin}}\theta + {\boldsymbol{F}_{{\rm{p}}f}}{\rm{cos}}\theta \\[4pt]{\boldsymbol{F}_{{\rm{py}}}} = {\boldsymbol{F}_{{\rm{py}}}}^{{\rm{fix}}} - {\boldsymbol{F}_{{\rm{pN}}}}{\rm{cos}}\theta + {\boldsymbol{F}_{{\rm{p}}f}}{\rm{sin}}\theta \\[4pt]{\boldsymbol{M}_{{\rm{po}}}} = {\boldsymbol{M}_{{\rm{po}}}}^{{\rm{fix}}} - {\boldsymbol{F}_{{\rm{pN}}}} \cdot {l_{\rm{1}}} - {\boldsymbol{F}_{{\rm{p}}f}} \cdot {l_{\rm{2}}}\end{array} \right.\end{align}

Based on the actual motion of the sliding pin, the unlocking conditions of the flange are as follows:

(25) \begin{align}\left\{ \begin{array}{l} {\boldsymbol{F}_{{\rm{px}}}} = 0 \\[4pt] {\boldsymbol{F}_{{\rm{py}}}} \lt 0 \\[4pt] {\boldsymbol{M}_{{\rm{po}}}} = 0 \end{array} \right.\end{align}

According to the established unlocking and separation conditions, it can be seen that the unlocking torque is related to aerodynamic force, friction coefficient, including angle of spiral chute and other factors. The relationship between the unlocking torque and aerodynamic angle-of-attack can be obtained through calculation, as shown in Fig. 6. According to the calculation results, when the angle-of-attack reaches the maximum 30°, the maximum unlocking torque ${M_{\rm{T}}}^{{\rm{max}}} = 2 {\rm{.064\, N/m}}$ is required.

Figure 6. Relation between unlocking torque and aerodynamic angle-of-attack.

3.4 Dynamic characteristic

Under the actual operating conditions, a comprehensive analysis is conducted to assess the aerodynamic properties of the individual body, the mechanical behaviour of the set pin, and the dynamics of the unlocking mechanism. By considering the various forces acting on the separation mechanism, the overall performance and functionality of the mechanism can be thoroughly evaluated. This thorough analysis ensures the mechanism’s effectiveness and reliability during operation.

A Menter’s shear stress transfer (SST) turbulence model with a cruise speed of V_f = 60 m/s, a cruise altitude of H = 1,000 m, a flight angle-of-attack that ranges from 0 to 30°, and a single maximum design mass of M = 3 kg is used by the atmospheric model during the simulation stage of aerodynamic characteristics. Based on the monoplane’s flight conditions, the aerodynamic loads are computed. The outcomes of the single-wing aerodynamic simulation analysis in this study are shown in Fig. 7. Table 1 displays the computation’s outcomes.

Figure 7. Aerodynamic simulation results of combined UAV.

Table 1. Aerodynamic load calculation results of single wing

The manoeuvering load and gust wind load during flight exacerbate the force condition of the stationary pin. The force condition of the stationary pin is further aggravated by the manoeuvering load and gust wind load experienced during flight. Therefore, it is crucial to perform a mechanical verification of the set pin to ensure that the maximum contact stress remains below the permissible stress of the material. This verification is necessary to ensure that the separation mechanism meets the design requirements under all operating situations. The set pin is constructed using the 7075 aluminum alloy, and Table 2 provides an overview of the material characteristics.

Table 2. Material parameters

A finite element model is developed to analyse the bearing structure and separation mechanism of the combined UAV. The model considers the application of the maximum pneumatic force on the single wing, allowing for the calculation of the stress distribution within the bearing structure under this force. The results of the calculations indicate that the highest stress concentration occurs at the middle two set pins, reaching a maximum value of 131 MPa. This finding is illustrated in Fig. 8, and it confirms that the stress levels are within the acceptable range for the mechanical properties of the material, satisfying the requirements.

Figure 8. Stress distribution under maximum force.

In order to determine the kinematic properties of the separation mechanism, an analysis was conducted on the separation dynamics of the mechanism throughout the entire mission cycle. The model used for analysis is illustrated in Fig. 9. The separation action time (T) is set to 1 second, and the longitudinal displacement, velocity, and acceleration data of the single wing during the separation process are obtained with the centre of mass O of the single wing serving as the reference point for attitude data, as depicted in Fig. 10. The calculation results reveal that both the single wing separation displacement curve and separation velocity curve exhibit sinusoidal characteristics. The separation acceleration data display sawtooth curves within a narrow range due to the influence of contact parameter settings such as material contact stiffness (k), force index (e), damping (c), and magnetic permeability (s). However, after being fitted with a nonlinear curve function, they still exhibit distinct characteristics of a sinusoidal function distribution. Equation (26) depicts the data-fitted sinusoidal curve equation.

(26) \begin{align}y = {y_0} + A{\rm{sin}}\left( {{\rm{\pi }}\frac{{\left( {x - {x_{\rm{c}}}} \right)}}{\omega }} \right)\end{align}

Figure 9. Separation kinetics analysis model.

Figure 10. Separation kinetic parameter curve.

It can be observed that the monoplane motion parameters, such as separation displacement, separation speed, and separation acceleration, do not experience sudden changes during the separation process. This indicates that the separation mechanism can fulfill the demand for fast, low-impact, and smooth separation tasks.

In the separation process, the force exerted by the single wing on the body wing primarily influences the aircraft’s rolling stability, while having minimal impact on its pitching and yawing moments. Therefore, this study focuses mainly on analysing the static rolling stability, as depicted in Fig. 11. The monomer applies a rolling moment of 0.75 N/m to the main body during separation, which is significantly lower than the maximum rolling moment. Hence, this paper demonstrates favourable characteristics of low impact for the proposed separation mechanism.

Figure 11. Rolling static stability curve.

4.1 Separation experiment

Based on the research conducted on the mathematical model and finite element model, a combined UAV experimental system was designed and constructed. This system was developed to simulate the hanging principle and provide an equivalent external force during the separation process of the single wing, as illustrated in Fig. 12. Subsequently, experimental research was conducted to investigate the separation of the single wing under aerodynamic load.

Figure 12. Pneumatic load simulation test platform.

Before the experiment started, the angle-of-attack of the experimental setup was adjusted to 3° in order to simulate the separation characteristics in the case of the optimal lift-to-drag ratio, and the sensor was adjusted to the position of the single wing centre of mass. According to the simulation calculation results (Table 1), the lift motor and drag motor were adjusted to make the load lift drag consistent with the aerodynamic simulation calculation results at the 3° angle-of-attack. Start the drive motor and collect the acceleration data during the separation of the monocoque, as shown in Figs. 13 and 14. Considering factors such as processing errors and response delays in the experiment, multiple separation experiments were conducted under 3° conditions, and the experimental results are shown in Fig. 15.

Figure 13. Separation experiment process: (a) single wing pre-separation state;and (b) single wing separation process.

Figure 14. Single wing separation acceleration curve.

The above five groups of data are analysed by superposition, and the mean data after superposition is fitted by nonlinear function. The fitting equation is presented in Equation (27). The experimental results show that the centroid acceleration in single wing separation satisfies the sinusoidal function characteristics.

(27) \begin{align}y = - 0{\rm{.01}} + {\rm{sin}}\left( {{\rm{\pi }}\frac{{\left( {x - 0{\rm{.58}}} \right)}}{{0{\rm{.49}}}}} \right)\end{align}

4.2 Analysis of influencing factors

In order to further study the safety of single wing separation process, this paper analyses the influence of different flight speeds and flight angle-of-attack on the separation process. The values of flight speed parameters are shown in Table 3, and the values of flight angle-of-attack are shown in Table 4.

Table 3. Flight speed parameters table

Table 4. Flight angle-of-attack parameter table

Figure 15. Acceleration stacking mean fitting function.

The law of motion variation can be ascertained by analysing the trend of velocity variation in the centroid of the single wing. Figure 16 presents the velocity curve of the single wing in the separation direction. The results indicate that as the angle-of-attack remains constant, the flight velocity gradually increases, subsequently augmenting the velocity of separation for the individual wing. Moreover, the findings reveal that alterations in flight velocity have no detectable effect on the separation process of the single wing. When the flight velocity remains steady and the flight angle-of-attack falls within the range of 3° to 5°, the separation velocity displays cosine-like characteristics. However, a significant alteration in the single wing’s velocity occurs at the 0.97-second mark when the angle-of-attack reaches 6°. Additionally, at an angle-of-attack of 7°, the velocity of the single wing also undergoes a sudden and pronounced change at 0.91 seconds. These findings indicate that the separation process is significantly influenced by the flight angle-of-attack, suggesting that the safe separation angle-of-attack should be maintained below 6°. Furthermore, the results demonstrate that the flight speed has minimal impact on the separation process.

Figure 16. Analysis results of influencing factors.