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Performance of a turbojet engine with fluidic thrust vectoring

Published online by Cambridge University Press:  11 April 2022

T. Chandra Sekar
Affiliation:
Department of Aerospace Engineering, Indian Institute of Technology Kanpur (IITK), Kanpur, Uttar Pradesh, India
R. H Sundararaj*
Affiliation:
Department of Aerospace Engineering, Indian Institute of Technology Kanpur (IITK), Kanpur, Uttar Pradesh, India
R. Arora
Affiliation:
Department of Aerospace Engineering, Indian Institute of Technology Kanpur (IITK), Kanpur, Uttar Pradesh, India
A. Kushari
Affiliation:
Department of Aerospace Engineering, Indian Institute of Technology Kanpur (IITK), Kanpur, Uttar Pradesh, India
*
*Corresponding Author. Email: [email protected]
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Abstract

The objective of the present work is to estimate the performance of a turbojet engine during Fluidic Thrust Vectoring (FTV) employed by injecting the secondary-jet at the throat of a convergent nozzle. The nozzle performance maps and effective nozzle throat area obtained from experiments are coupled with the performance of a conventional engine (without FTV) using an iterative algorithm developed as a part of this work. The performance is estimated for different flow rates of secondary-jet sourced either from a separate compressor or the engine’s compressor. During FTV, the operating point shifted towards the surge line with increased turbine entry temperature. The desired and obtained vector angles and thrust magnitudes are different. At high secondary-jet flow rates, the turbine operation moved out of its performance map. These aspects should be incorporated while integrating the FTV at the system level, thus, asserting the importance of FTV studies coupled with engine performance.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of Royal Aeronautical Society

Nomenclature

A

area (m2)

${A_{{\rm{te}}}}$

effective nozzle throat area (m2)

${A_{{\rm{tg}}}}$

geometric nozzle throat area (m2)

${{\rm{C}}_{\rm{o}}},{{\rm{C}}_1},\;{{\rm{C}}_2}$

constants

FTV

fluidic thrust vectoring

${\dot m_{\rm{f}}}$

mass flow rate of fuel (kg/s)

${\dot m_i}$

mass flow rate of air at i th station (kg/s)

${m_{i,{\rm{corr}}}}$

corrected mass flow rate at i th station (kg/s)

N

engine rotor speed (rpm)

NPR

nozzle pressure ratio

P

pressure (N/m2)

PLA

pilot lever angle

R

gas constant (J/kg-K)

rpm

rotation per minute

T

temperature (K)

TET

turbine entry temperature (K)

${\overrightarrow{\bf T}}$

thrust vector ( ${{\rm T}_{{\rm{axial}}}}\hat{{\bf I}}+{{\rm T}_{{\rm{yaw}}}}\hat{{\bf J}}+{{\rm T}_{{\rm{pitch}}}}\hat{{\bf K}}{\rm N}$ )

${T_{{\rm{axial}}}}$

thrust along the axial direction (N)

${T_{{\rm{pitch}}}}$

thrust along the pitch direction (N)

${T_{{\rm{yaw}}}}$

thrust along the yaw direction (N)

V

flow speed (m/s)

$\Delta {A_{{\rm{te}}}}$

change in the effective nozzle throat area (m2)

$\rho$

density (kg/m3)

${\theta _{\rm{y}}}$

vector angle (deg.)

$\gamma $

ratio of the specific heats

${{\rm{\pi }}_{\rm{c}}}$

compressor pressure ratio

Subscripts

a

atmosphere/ambient

b or 3b

bleed

corr

corrected value

D

design condition

eng

engine

in

inlet

m

measured value

n

normalised value

${\rm{oi}}$

total condition at i th station

r

relative

ref

reference value

s

secondary-jet

t

throat

Subscripts/Station Numbers

1

intake inlet/ambient

2

compressor inlet or intake exit

3

combustor inlet or compressor exit

4

turbine inlet or combustor exit

7

nozzle inlet

8

nozzle exit/throat

1.0 Introduction

Next-generation aircraft are characterised by higher range, loiter capability, less weight, volume, drag, noise, fuel burn and short take-off and landing (STOL) capabilities. Along with these, the aircraft is to be incorporated with a tailless planform to reduce drag [Reference Miller and Flamn1]. Using engine thrust for pitch and yaw control by means of “Thrust Vectoring” is a suitable alternative for the tail (rudder and elevators). Thrust vectoring also helps carry out extreme manoeuvres and STOL capabilities, which would not be possible with conventional control surfaces owing to their aerodynamic limitations. Furthermore, the post-stall handling ability of an aircraft can be enhanced by incorporating thrust vectored flight control systems in an aircraft. Thrust vectored flight control enables an aircraft to stabilise beyond the limits posed by the external flow regime [Reference Gal-Or2] and can be instrumental in preventing catastrophic failure [Reference Gal-Or, Sherbaum and Lichtsinder3]. For naval applications, implementing thrust vectored flight control can eliminate the need for catapult launchers and arresters on carrier ship decks. Lockheed Martin F-22 Raptor, Sukhoi Su-30MKI, Lockheed Martin F-35, Harrier Jump Jet are equipped with a mechanical thrust vectoring nozzle(s). In summary, thrust vectored flight control transfers the flight controls to the engine from conventional control surfaces, which helps overcome the limitations posed by conventional control surfaces.

Thrust vectoring is accomplished by deflecting the thrust away from the centreline, which leads to the generation of forces and moments in the yaw and pitch directions. Thrust vectoring can be broadly classified under two categories, mechanical thrust vectoring and fluidic thrust vectoring (FTV). Mechanical thrust vectoring can be employed by gimbaling the nozzle or introducing deflecting vanes/flaps to achieve vectoring of the exhaust jet [Reference Gal-Or4]. Even though mechanical thrust vectoring is an effective approach to vectoring the jet, it requires integrating mechanical systems that can be complex and bulky, increasing the overall weight of the engine. On the contrary, FTV is simple to implement with a minimum weight penalty since no additional moving parts are required. FTV employs a secondary stream (secondary-jet) in addition to the primary flow to create the desired effect of displacing the primary flow from its centre line. Prominent methods for FTV in subsonic and supersonic nozzles are co-flow, counter-flow, shock vectoring, throat skewing and subsonic skewing [Reference Miller and Flamn1]. Yagle et al. [Reference Yagle, Miller, Ginn and Hamstra5] established that the throat skewing yielded higher gross thrust efficiency than other methods. The experimental study on a converging nozzle has shown that the secondary-jet injection at the nozzle exit deflects the thrust and forces the nozzle to operate at a reduced effective flow area [Reference Mcardle6]. The effect of the secondary-jet is maximum when the injection slot is at the exit [Reference Mcardle6]. These studies emphasised the flow dynamics during vectoring and evaluated the performance in terms of vector angle and thrust coefficient on a stand-alone nozzle. It is vital to acknowledge that in practice, the nozzle is attached to a gas turbine engine which is in turn fixed to the airframe. As reported by Lee and Lan [Reference Lee and Lan7], different optimal thrust deflection angles exist for the sustained maximum load factor, turn rate, and minimum turn radius. The earlier experimental studies [Reference Sekar, Kushari, Mody and Uthup8, Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9] on FTV showed that secondary-jet injection results in pressure rise at the nozzle inlet, which is expected to affect the engine operation. Additionally, the change in the effective flow area of the nozzle [Reference Mcardle6] may result in compressor surge or higher turbine entry temperature [Reference Sundararaj, Sekar, Arora, Rao and Kushari10]. Thus, it is evident that using FTV will affect engine operation, moving it away from its initial operating point.

In an aircraft, the engine core (Fig. 1) is designed by the engine manufacture, whereas the nozzle and intake are part of the airframe. Engine core, intake, and nozzle should work in harmony for optimum performance. The interaction between the components in the engine is analysed using their performance maps, which are a graphical representation of the corrected parameters (non-dimensional) governing the component operation [Reference Cohen, Rogers and Saravanamuttoo11]. The details of these component performance maps and how they are used for component matching are available in the open literature [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9, Reference Sieros, Stamatis and Mathioudakis12]. The interaction between the components of a turbojet engine (Fig. 1) can be understood using thermodynamic cycle (Brayton cycle) analysis [Reference Kurzke13Reference Baig and Saravanamuttoo15]. This exercise is termed ‘performance simulation of a gas turbine engine’ and can be carried out using commercially available software. The performance simulation includes two steps: design point calculation and off-design calculation. The design point calculation comprises the engine’s selection that involves selecting intake, compressor, combustor, turbine and nozzle. The off-design analysis includes estimating the engine performance at different operating conditions (including flight speed, altitude, and thrust level/engine rotor speed), i.e. evaluating the performance of the chosen components at different flight conditions. Commercially available simulation software are not capable of simulating engine performance during FTV operations since the nozzle performance maps for FTV [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9] are not included. Thus, the effect of FTV on engine performance cannot be directly studied using existing performance simulation software. However, the software allows the user to change parameters related to the nozzle during off-design simulations. Using this feature and the performance maps for FTV [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9], the performance of a jet engine could be estimated during FTV, and this forms the basis for the present work.

Figure 1. Components of a single-spool turbojet engine.

The objective of the present work is to estimate the performance of a single-spool turbojet engine during FTV. The novelty of the current work is the algorithm developed for coupling the experimental data from nozzle testing for FTV [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9] and the commercially available performance simulation software, Gasturb 13. The algorithm developed as a part of this work helps transfer the information from experiments on FTV capable nozzle to the performance simulation software, allowing estimation of engine performance during FTV. In the first part of this manuscript, the nozzle performance maps from the earlier experimental work [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9] to implement FTV in the yaw direction in a convergent nozzle are discussed. In the second part of the manuscript, the basics associated with the performance/operation of a turbojet engine and modelling are discussed. In the third part of the manuscript, the coupling mechanism between the experimental data and the simulation software is discussed, followed by the algorithm adopted to study the performance of the engine during FTV. In the last section, the performance of the single-spool turbojet engine during FTV is discussed.

2.0 Nozzle performance maps for FTV

The performance maps for the nozzle with FTV using secondary-jet injection from the earlier experimental study [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9] and their mathematical formulations required for simulations are discussed in this section.

For an FTV nozzle, three performance maps are required, namely (1) NPR-map, (2) T-map (Thrust-map) and (3) θ-map (vector angle map) [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9]. The definitions of the parameters used in these maps are given by Equations (1)–(5) after incorporating modifications to the earlier definitions [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9] to match the definitions used in the simulation software. These modifications are in terms of the reference conditions, thus only scaling the numerical values leaving the overall trend unaltered. The reference conditions are a temperature ( ${T_{{\rm{ref}}}})$ of 288.15K and pressure ( ${P_{{\rm{ref}}}})$ of 101,325Pa.

The corrected mass flow rate calculated at the inlet of the nozzle $\left( {{m_{7,{\rm{corr}}}}} \right)$ is given by Equation (1), where ${\dot m_7}$ is the mass flow rate, ${T_{{\rm{o}}7}}$ is the stagnation temperature, ${P_{{\rm{o}}7}}$ is the stagnation pressure at the nozzle inlet.

(1) \begin{equation}{\rm{Corrected\;mass\;flow\;rate\;at\;the\;nozzle\;inlet\;}}\left( {{m_{7,{\rm{corr}}}}} \right) = \frac{{{{\dot m}_7}\sqrt {{T_{{\rm{o}}7}}/{T_{{\rm{ref}}}}} }}{{{P_{{\rm{o}}7}}/{P_{{\rm{ref}}}}}}{\rm{\;kg}}/{\rm{s}}\end{equation}

The corrected mass flow rate of the secondary-jet $\left( {{m_{{\rm{s}},{\rm{corr}}}}} \right)$ at the exit of the secondary-jet injection slot is given by Equation (2), where ${\dot{m}}_{\rm{s}}$ is the mass flow rate, ${T_{{\rm{os}}}}$ is the stagnation temperature, ${P_{{\rm{os}}}}$ is the stagnation pressure of the secondary-jet.

(2) \begin{equation}{\rm{Corrected\;mass\;flow\;rate\;of\;secondary}} - {\rm{jet\;}}\left( {{m_{{\rm{s}},{\rm{corr}}}}} \right) = \frac{{{{\dot m}_{\rm{s}}}\sqrt {{T_{{\rm{os}}}}/{T_{{\rm{ref}}}}} }}{{{P_{{\rm{os}}}}/{P_{{\rm{ref}}}}}}\;{\rm{\;kg}}/{\rm{s}}\end{equation}

The nozzle pressure ratio (NPR) is given by Equation (3), where ${P_{{\rm{o}}7}}$ is the stagnation pressure at nozzle inlet and ${P_{\rm{a}}}$ is the atmospheric pressure.

(3) \begin{equation}{\rm{Nozzle\;Pressure\;Ratio\;}}\left( {{\rm{NPR}}} \right) = \frac{{{P_{{\rm{o}}7}}}}{{{P_{\rm{a}}}}}\end{equation}

Normalised thrust is given by Equation (4), where $ {{\overrightarrow{\bf{T}}}_{\bf{m}}} = {T}_{\rm axial} \hat{\bf{I}} +{T}_{\rm yaw} \hat{\bf{J}} + {T}_{\rm pitch}\hat{\bf{K}} $ is obtained from the experiments, and $\big| {{{{\overrightarrow{\bf T}}}_{\bf{D}}}} \big|$ is the design value of the thrust magnitude (i.e. with Mach number equal to one at the throat).

(4) \begin{equation}{\rm{Normalised\;Thrust\;}}\big( {\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big|} \big) = \frac{{\big| {{{{\overrightarrow{\bf T}}}_{\bf{m}}}} \big|}}{{\big| {{{{\overrightarrow{\bf T}}}_{\bf{D}}}} \big|}}\end{equation}

The yaw vector angle ( ${\theta _{\rm{y}}}$ ) is given by Equation (5), where ${T_{{\rm{yaw}}}}$ is the yaw component and ${T_{{\rm{axial}}}}$ is the axial component of the thrust.

(5) \begin{equation}{\rm{Yaw\;vector\;angle\;}}\left( {{\theta _{\rm{y}}}} \right) = {\tan ^{ - 1}}\left( {{T_{{\rm{yaw}}}}/{T_{{\rm{axial}}}}} \right)\end{equation}

The three performance maps are shown in Fig. 2(a) (NPR-map), (b) (T-map), and (c) (θ-map). For a given ${{{m}}_{{\rm{s}},{\rm{corr}}}}$ , the $\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big|$ varies quadratically with ${{{m}}_{7,{\rm{corr}}}}$ (Fig. 2(b)), and the magnitude of ${{\rm{\theta }}_{\rm{y}}}$ varies linearly with ${{{m}}_{7,{\rm{corr}}}}$ (Fig. 2(c)). Thus, for the given combination of ${{{m}}_{{\rm{s}},{\rm{corr}}}}$ and ${{{m}}_{7,{\rm{corr}}}}$ , the thrust magnitude $\big( {\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big|} \big)$ and vector angle $\big( {{\theta _{\rm{y}}}} \big)$ can be determined using Equations (6) and (7), respectively, and the values of the coefficients are given in Table 1. Equations (6) and (7) are used in the simulations for estimating ${\theta _{\rm{y}}}$ and $\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big|$ .

(6) \begin{equation}\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big| = {{\rm{C}}_2}{\left( {{m_{7,{\rm{corr}}}}} \right)^2} + {{\rm{C}}_1} \times {m_{7,{\rm{corr}}}} + {{\rm{C}}_0},{\rm at}\,{m_{{\rm{s}},{\rm{corr}}}} = {\rm constant} \end{equation}
(7) \begin{equation}{{\rm{\theta }}_{\rm{y}}} = {{\rm{C}}_1} \times {m_{7,{\rm{corr}}}} + {{\rm{C}}_0},{\rm{at}}\,{m_{{\rm{s}},{\rm{corr}}}} = {\rm{constant}}\end{equation}

Table 1. Values of coefficients in Equation (6) (T-map), Equation (7) (θ-map) and Equation (12) ( $\% \Delta {A_{{\bf{te}}}}$ ) for different ${m_{{{s}},{{corr}}}}$

Figure 2. Nozzle performance maps (a) NPR-map, (b) T-map, and (c) θ-map for the nozzle.

The plots in NPR-map (Fig. 2(a)) shifts downwards with an increase in ${m_{{\rm{s}},{\rm{corr}}}}$ . Thus, at a given NPR, the ${m_{7,{\rm{corr}}}}$ reduces due to the reduction in effective nozzle throat area [Reference Sekar, Kushari, Mody and Uthup8, Reference Cohen, Rogers and Saravanamuttoo11]. The magnitude of the effective nozzle area change ( ${\rm{\% }}\Delta {A_{{\rm{te}}}}$ ) is computed using Equation (8), where ${A_{{\rm{te}}}}$ is effective throat area and ${A_{{\rm{tg}}}}$ is geometric throat area.

(8) \begin{equation} {\rm{\%\ Change\ in\ the\ effective\ throat\ area }} \left( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \right) = \left( {\frac{{{A_{{\rm{te}}}} - {A_{{\rm{tg}}}}}}{{{A_{{\rm{tg}}}}}}} \right) \times 100\end{equation}

The effective throat area ( ${A_{{\rm{te}}}}$ ) is computed using Equation (9), where ${\dot m_7}$ is the mass flow rate, ${\rho _{\rm{t}}}$ is the flow density at the nozzle throat, and ${V_{\rm{t}}}$ is the flow speed at the nozzle throat, obtained from experiments.

(9) \begin{equation}{\rm{Effective\;Throat\;Area\;}}\left( {{A_{{\rm{te}}}}} \right) = \frac{{{{\dot m}_7}}}{{{\rho _{\rm{t}}}{V_{\rm{t}}}}}\end{equation}

Flow velocity at the nozzle throat ( ${V_{\rm{t}}}$ ) is computed using Equation (10) assuming isentropic flow, where ${P_{{\rm{o}}7}}$ is stagnation pressure at nozzle inlet, ${P_{\rm{t}}}$ is the static pressure at the nozzle throat, obtained from experiments. Nevertheless, the nozzle flow and secondary-jet interaction is an irreversible process associated with pressure loss. Since the secondary-jet is injected close to the nozzle exit, it is safe to assume that the flow remains isentropic up to the injection slot.

(10) \begin{equation}{V_{\rm{t}}} = \sqrt {\frac{{2{{\gamma R}}{{{T}}_{{\rm{o}}7}}}}{{\gamma - 1}}\left( {1 - {{\left( {\frac{{{P_{{\rm{o}}7}}}}{{{P_{\rm{t}}}}}} \right)}^{\frac{{1 - \gamma }}{{\rm{\gamma }}}}}} \right)} \end{equation}

The flow density at nozzle throat ( ${\rho _{\rm{t}}}$ ) is calculated using Equation (11), where ${P_{\rm{t}}}$ is the static pressure measured at the nozzle throat, and ${T_{\rm{t}}}$ is the static temperature at the nozzle throat estimated from the measured ${T_{{\rm{o}}7}}$ assuming isentropic flow.

(11) \begin{equation}{\rho _{\rm{t}}} = \frac{{{P_{\rm{t}}}}}{{{\rm{R}}{{{T}}_{\rm{t}}}}}\end{equation}

Figure 3 shows $\% \Delta {A_{{\rm{te}}}}$ vs. ${m_{7,{\rm{corr}}}}$ for different ${m_{{\rm{s}},{\rm{corr}}}}$ . The dashed line corresponding to each ${m_{{\rm{s}},{\rm{corr}}}}$ shows the trend obtained by curve fitting using regression analysis. As observed from the plot, the values of $\% \Delta {A_{{\rm{te}}}}$ are negative, indicating that the effective throat area ( ${A_{{\rm{te}}}}$ ) is less than the geometric throat area ( ${A_{{\rm{tg}}}}$ ). For a given ${m_{7,{\rm{corr}}}}$ , the magnitude of $\% \Delta {A_{{\rm{te}}}}$ increases with an increase in ${m_{{\rm{s}},{\rm{corr}}}}$ . Since $\% \Delta {A_{{\rm{te}}}}$ is negative, it may be concluded that the effective throat area reduces with an increase in ${m_{{\rm{s}},{\rm{corr}}}}$ . The trend lines in the figure show a linear relationship between the $\% \Delta {A_{{\rm{te}}}}$ and ${m_{7,{\rm{corr}}}}$ at any given value of ${m_{{\rm{s}},{\rm{corr}}}}$ and the slope depends on ${m_{{\rm{s}},{\rm{corr}}}}$ . Thus, the value of $\% \Delta {A_{{\rm{te}}}}$ can be expressed as a function of ${m_{{\rm{s}},{\rm{corr}}}}$ using Equation (12). The values of the constants in Equation (12) is given in Table 1.

(12) \begin{equation}{\rm{\% }}\Delta {A_{{\rm{te}}}} = {{\rm{C}}_1} \times {m_{7,{\rm{corr}}}} + {{\rm{C}}_0}\end{equation}

Figure 3. Nozzle throat area change ( $\% \Delta {{{A}}_{{\rm{te}}}}$ ) vs. ${{{m}}_{7,{\rm{corr}}}}$ at different ${{{m}}_{{\rm{s}},{\rm{corr}}}}$ .

3.0 Engine model and algorithm for FTV simulation

The elements of the engine modelling using the simulation software are discussed in the first part of this section, followed by the algorithm and the engine performance. The first part is intended to establish the connection between the experimental data and the simulation software, along with the rationale behind the algorithm developed for the analysis. Although Gasturb 13 [Reference Gasturb and Manual16] is used for simulations in this study, the procedure would remain the same for other commercially available software or in-house codes.

3.1 Engine model

The performance of a single-spool turbojet engine can be evaluated by modelling its thermodynamic cycle [Reference Cohen, Rogers and Saravanamuttoo11] (Brayton cycle). The key performance parameters are thrust, thrust specific fuel consumption, surge margin, and turbine entry temperature (TET). The operational envelope of a turbojet engine is limited by the compressor surge margin and turbine entry temperature (TET). For a thrust vector enabled engine, the vector angle is added to the list of performance parameters. Among these performance parameters, thrust, vector angle, turbine entry temperature (TET) and surge margin are of interest in this study. A single spool turbojet jet engine chosen for current simulations is suitable for micro-air vehicle applications. However, the findings may be extended to the other gas turbines employing fluidic thrust vectoring.

The components of the single-spool turbojet engine chosen for the simulation and the station numbers are shown in Fig. 4. The single-spool turbojet engine comprises a single-stage compressor (between Station-2 and Station-3) mechanically connected to a single-stage turbine (between Station-4 and Station-5) via a shaft. The air to the compressor is supplied by an intake (between Station-1 and Station-2). A combustor (between Station-3 and Station-4) is placed between the compressor and turbine in which the aviation turbine fuel (Jet-A1) is combusted for energy addition. A convergent-type nozzle (between Station-7 and Station-8) with the throat at Station-8 is present at the exit of the turbine to convert the pressure energy to jet velocity producing thrust. The inter-component duct (between Station-5 and Station-7) connecting the turbine exit and the nozzle inlet is assumed to have no effect on the thermodynamic properties of the flow. The fuel is supplied into the combustion chamber by the fuel pump (Fig. 4). The fuel pump is operated by the FADEC (Full Authority Digital Engine Control) [Reference Davies, Hoelzer and Vizzini17] based on the input from the pilot using ‘pilot-lever’. In an actual engine, the parameters, including the engine rotor speed, exhaust gas temperature, and compressor exit temperature, are monitored by the FADEC, and the fuel flow rate is controlled based on these parameters and the control input from the pilot. By changing the pilot lever, the thrust from the engine can be varied.

Figure 4. Schematic showing components and station numbers used.

3.1.1 Modelling the nozzle used in experiments

The first stage of modelling comprises design point calculation, and the second stage comprises off-design calculations. The design point is modelled based on the shape and size of the nozzle used in experiments [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9]. The nozzle shape is carried over as discharge coefficient, and the nozzle size is carried over as nozzle throat area. During the design point calculations, the discharge coefficient is an input parameter (among other parameters), and the nozzle throat area is an output parameter. Thus, during the design point calculations, the value of the discharge coefficient obtained from the experiments [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9] is given as an input, and the mass flow rate through the engine (another input parameter) was modified such that the geometric throat area of the nozzle estimated by the simulation software is equal to the nozzle throat area used in the experiments [Reference Sekar, Jaiswal, Arora, Sundararaj, Kushari and Acharya9]. As a result of this, both the corrected mass flow rate at the nozzle inlet $\left( {{m_{7,{\rm{corr}}}}} \right)$ and the thrust magnitude from the simulations and experiments is equal.

The design point values of the engine used in this simulation are given in Table 2. For off-design simulations, the compressor and turbine maps available in Gasturb 13® are used for current simulations. Zero pressure loss in the intake is assumed ( ${P_{{\rm{o}}2}} = {P_{\rm{a}}}$ ).

Table 2. Design point parameters of the turbojet engine chosen for simulation

*All other parameters were kept at their default values.

3.1.2 Sourcing the secondary-jet

Two options are considered for sourcing the secondary-jet required for vectoring, as shown in Fig. 4. The first option is to have an additional compressor different from the compressor in the jet engine, and the second option is to take the air from the compressor exit (station 3) of the core. The operation of this additional compressor is independent of the turbojet engine under study. A selector switch in the secondary-jet line is conceptualised for choosing the source, as indicated in Fig. 4. The secondary-jet line can be connected to either ‘A’ or ‘B’ based on the source of the secondary-jet. The practicality of the additional compressor (and the selector switch) is debatable and would depend on the engine and the final requirements. The secondary-jet sourcing concept may change for other engine categories (multi-spool turbojet and turbofan). Since the present study is aimed to study the effect of bleed on engine operation during FTV, the concept shown in Fig. 4 is considered.

3.1.3 Engine performance parameters

The compressor pressure ratio ( ${{\rm{\pi }}_{\rm{c}}}$ ) is given by Equation (13) where ${P_{{\rm{o}}2}}$ is the total pressure at the compressor inlet, and ${P_{{\rm{o}}3}}$ is the total pressure at the compressor exit.

(13) \begin{equation}{\rm{Compressor\;pressure\;ratio\;}}\left( {{{\rm{\pi }}_{\rm{c}}}} \right) = \frac{{{P_{{\rm{o}}3}}}}{{{P_{{\rm{o}}2}}}}\end{equation}

The corrected mass flow rate at compressor inlet ( ${m_{2,{\rm{corr}}}}$ ) is given by Equation (14), where ${\dot m_2}$ is the mass flow rate, ${P_{{\rm{o}}2}}$ is the total pressure, ${T_{{\rm{o}}2}}$ is the total temperature all at the compressor inlet.

(14) \begin{equation}{\rm{Corrected\;mass\;flow\;rate\;at\;the\;compressor\;inlet\;}}\left( {{m_{2,{\rm{corr}}}}} \right) = {\rm{\;}}\frac{{{{\dot m}_2}\sqrt {{T_{{\rm{o}}2}}/{T_{{\rm{ref}}}}} }}{{{P_{{\rm{o}}2}}/{P_{{\rm{ref}}}}}}\;{\rm{kg}}/{\rm{s}}\end{equation}

The relative corrected rotor speed ( ${N_{{\rm{corr}},{\rm{r}}}}$ ) is given by Equation (15), where $N$ is the rotor speed and ${T_{{\rm{o}}2}}$ is the total temperature at the compressor inlet during actual operation. ${N_{\rm{D}}}$ is the rotor speed, ${T_{{\rm{o}}2,{\rm{D}}}}$ is the total temperature at the compressor inlet at the design point, and ${T_{{\rm{ref}}}}$ is the reference value (288.15K).

(15) \begin{equation}{\rm{Relative\;corrected\;rotor\;speed\;}}\left( {{N_{{\rm{corr}},{\rm{r}}}}} \right) = {\rm{\;}}\frac{{N/\sqrt {{T_{{\rm{o}}2}}/{T_{{\rm{ref}}}}} }}{{{N_{\rm{D}}}/\sqrt {{T_{{\rm{o}}2,{\rm{D}}}}/{T_{{\rm{ref}}}}} }}\end{equation}

The corrected mass flow rate of the bleed taken from the compressor exit is given by Equation (16) where ${\dot m_{\rm{b}}}$ is the mass flow rate of the bleed, ${P_{{\rm{o}}3}}$ is the total pressure at the compressor exit, ${T_{{\rm{o}}3}}$ is the total temperature at the compressor exit.

(16) \begin{equation}{\rm{Corrected\;mass\;flow\;rate\;of\;bleed\;}}\left( {{m_{3{\rm{b}},{\rm{corr}}}}} \right) = \frac{{{{\dot m}_{\rm{b}}}\sqrt {{T_{{\rm{o}}3}}/{T_{{\rm{ref}}}}} }}{{{P_{{\rm{o}}3}}/{P_{{\rm{ref}}}}}}{\rm{\;kg}}/{\rm{s}}\end{equation}

3.2 Algorithm for incorporating FTV in the simulation software

Employing FTV is considered under the off-design operation of the jet engine. During off-design operation, the nozzle throat area ( ${A_8}$ ), nozzle thrust coefficient, and discharge coefficient can be varied. As observed earlier in Fig. 3, secondary-jet injection reduces the effective nozzle throat area ( ${A_{{\rm{te}}}}$ ). Thus, the FTV can be simulated as the nozzle throat area at station-8 ( ${A_8}$ ) in off-design simulations. Based on the flow rate through the nozzle and the secondary-jet, the nozzle throat area change ( ${\rm{\% }}\Delta {{{A}}_{{\rm{te}}}}$ ) can be estimated from Equation (12). This change in the throat area ( ${\rm{\% }}\Delta {A_{{\rm{te}}}}$ ) is given as a change in the nozzle area at station-8 ( ${\rm{\% }}\Delta {A_8}$ ) in the off-design simulations. For example, if ${m_{7,{\rm{corr}}}} = $ 0.154 and ${m_{{\rm{s}},{\rm{corr}}}} = 2.71\; \times {10^{ - 3}}$ , then a throat area change ( ${\rm{\% }}\Delta {A_8}$ ) equal to −2.56% is entered into the simulation software, and the new operating point is calculated. This new operating point has ${{{m}}_{7,{\rm{corr}}}}$ different from 0.154. Thus, the ${\rm{\% }}\Delta {A_{{\rm{te}}}}$ at this new operating point would be different from −2.56% and the new ${\rm{\% }}\Delta {A_{{\rm{te}}}}$ is considered. The procedure is repeated until the area changes converge. The algorithm is best described using the flow chart in Fig. 5(a). To minimise complexities, all the simulations are carried out assuming steady-state operation. Thus, a change in the throat area of the nozzle instantly drives the engine to a new operating point without considering transient operations, i.e. the inertia effects are ignored (both thermodynamic and mechanical). It is vital to note that the final operating point predicted both with and without considering the inertial effects would be the same, but the path taken would be different. Since the objective is to understand the effect on the steady-state operation, satisfactory results would be obtained using this algorithm.

Figure 5. Algorithm for estimating the response of the engine during fluidic thrust vectoring, (a) flow chart, (b) convergence with the iteration number.

Consider the engine operating at a relative corrected rotor speed of ${\left( {{N_{{\rm{corr}},{\rm{r}}}}} \right)_{{\rm{start}}}}$ , at which the corrected mass flow rate at the nozzle inlet (station 7) is given by ${\left( {{m_{7,{\rm{corr}}}}} \right)_{{\rm{start}}}}$ . This operating condition is termed as ‘starting-point’. Step 1, the secondary-jet with ${m_{{\rm{s}},{\rm{corr}}}}$ is activated and is maintained constant for all the subsequent steps. Step 2, the change in the nozzle throat area ${\left( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \right)_{{\rm{step}}2}}$ is estimated using Equation (12) corresponding to the chosen ${\left( {{m_{7,{\rm{corr}}}}} \right)_{{\rm{start}}}}$ and ${m_{{\rm{s}},{\rm{corr}}}}$ . Step 3, the value of ${\left( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \right)_{{\rm{step}}2}}$ is input to the software (off-design operation), yielding a new operating point for the engine, and value of ${\left( {{m_{7,{\rm{corr}}}}} \right)_{{\rm{step}}3}}$ is computed. Step 4, using the values of ${\left( {{m_{7,{\rm{corr}}}}} \right)_{{\rm{step}}3}}$ and ${m_{{\rm{s}},{\rm{corr}}}}$ , the new nozzle throat area change ${\left( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \right)_{{\rm{step}}4}}$ is calculated using Equation (12). Step 5, the value $\big| {{{\left( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \right)}_{{\rm{step}}2}} - {{\left( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \right)}_{{\rm{step}}4}}} \big|$ is computed, and if it is within the chosen tolerance limit, the computations are stopped. Otherwise, the ${\left( {{m_{7,{\rm{corr}}}}} \right)_{{\rm{step}}3}}$ is given as input to step 2, and steps 2 to 5 are repeated until the convergence criterion is satisfied at step 5. After the convergence criterion is met, the new operating point at step 3 is the final equilibrium operating point of the jet engine after the secondary-jet injection.

The algorithm is demonstrated in Fig. 5(b) using the case of ${\big( {{m_{7,{\rm{corr}}}}} \big)_{{\rm{start}}}} = $ 0.155 and ${m_{{\rm{s}},{\rm{corr}}}} = 2.71 \times {10^{ - 3}}$ . The open diamonds show the value of ${\big( {{m_{7,{\rm{corr}}}}} \big)_{{\rm{step}}3}}$ during each iteration and open squares show the value of $\big| {{{\big( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \big)}_{{\rm{step}}2}} - {{\big( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \big)}_{{\rm{step}}4}}} \big|$ during each iteration. Iteration number zero corresponds to the starting point in the algorithm, and iteration number 7 corresponds to the new operating point. As observed from the plot, the quantity $\big| {{{\big( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \big)}_{{\rm{step}}2}} - {{\big( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \big)}_{{\rm{step}}4}}} \big|$ decreases with each iteration and reaches convergence. The value of ${m_{7,{\rm{corr}}}}$ at new operating point is different from that of the starting point. Similarly, other parameters at the new operating point are different from the starting point. In step 3, if the operating point crosses the surge line leading to instability, the algorithm is terminated, and the case is termed ‘Not-Converged’. It may be concluded that the FTV may not be implemented for these combinations of ${m_{7,{\rm{corr}}}}$ and ${m_{{\rm{s}},{\rm{corr}}}}$ .

4.0 Engine performance during FTV

The engine performance without FTV is considered in the first part of this section, followed by the performance with FTV. The results of the first part would help explain the performance during FTV.

4.1 Engine performance without FTV (conventional engine)

The thrust from the engine is varied by changing the fuel flow rate using the pilot-lever (Fig. 4). The relative corrected value of the rotor speed ( ${N_{{\rm{corr}},{\rm{r}}}}$ ) at different fuel flow rates ( ${\dot m_{\rm{f}}}$ ) is shown in Fig. 6(a), and normalised thrust $\big( {\big| {{{{\overrightarrow{\bf T}}}_{{\bf{n}},{\bf{eng}}}}} \big|} \big)$ vs. fuel flow rate ( ${\dot m_{\rm{f}}}$ ) is shown in Fig. 6(b). The fuel flow rate is reduced by decreasing the pilot lever angle (PLA) and vice-versa. Both the figures show plots corresponding to different values of ${m_{3{\rm{b}},{\rm{corr}}}}$ . The case with no bleed extraction ( ${{{m}}_{3{\rm{b}},{\rm{corr}}}} = $ 0) is discussed first, followed by other cases. As observed in the plots, both the rotor speed and thrust increases with an increase in the fuel flow rate. The rate of change of ${N_{{\rm{corr}},{\rm{r}}}}$ with ${{\dot{m}}_{\rm{f}}}$ is large for $1.5 \times {10^{ - 3}} \lt {\dot m_{\rm{f}}} \lt 2 \times {10^{ - 3}}$ compared to ${\dot m_{\rm{f}}} \gt 2 \times {10^{ - 3}}$ kg/s (Fig. 6(a)). The rate of change of $\big| {{{{\overrightarrow{\bf T}}}_{{\bf{n}},{\bf{eng}}}}} \big|$ with ${\dot m_{\rm{f}}}$ is large for $1.5 \times {10^{ - 3}} \lt {\dot m_{\rm{f}}} \lt 2 \times {10^{ - 3}}$ compared to ${\dot m_{\rm{f}}} \gt 2 \times {10^{ - 3}}$ kg/s (Fig. 6(b)). The energy added is directly proportional to the fuel flow rate, thus, the energy available to the turbine is directly proportional to the amount of fuel added per second. The excess energy available to the turbine accelerates the rotor speed to a higher value which increases the mass flow rate and compressor pressure ratio (Fig. 7). At any given fuel flow rate, with the bleed from the exit of the compressor ( ${m_{3{\rm{b}},{\rm{corr}}}} \gt $ 0), the rotor speed reduces, and the magnitude of this decrement increases with an increase in ${m_{3{\rm{b}},{\rm{corr}}}}$ .

Figure 6. (a) Relative corrected speed ( ${{{N}}_{{\rm{corr}},{\rm{r}}}}$ ) vs. fuel flow rate ( ${{\dot{m}}_{\rm{f}}}$ ), (b) Normalised thrust from the engine $\big( {\big| {{{{\overrightarrow{\bf T}}}_{{\bf{n}},{\bf{eng}}}}} \big|} \big)$ vs. fuel flow rate ( ${{\dot{m}}_{\rm{f}}}$ ), for different bleeds ( ${{{m}}_{3{\rm{b}},{\rm{corr}}}}$ ) at compressor exit.

Figure 7. Compressor map showing the engine operating points during engine operation without ( ${{{m}}_{3{\rm{b}},{\rm{corr}}}} = $ 0) and with bleed ( ${{{m}}_{3{\rm{b}},{\rm{corr}}}} \gt $ 0).

The performance is better understood by plotting the engine operating points on the compressor map shown in Fig. 7. The inserts in the figure show the zoomed-in view of the plots for better visibility of the data points. For a conventional engine, the operating points on the compressor map correspond to the throttle change. The operating line for different ${{{m}}_{3{\rm{b}},{\rm{corr}}}}$ is shown in Fig. 7. For ${m_{3{\rm{b}},{\rm{corr}}}} = $ 0, with an increase in throttle, the rotor speed, mass flow rate, and compressor pressure ratio increase leading to an increase in the thrust as observed earlier in Fig. 6. With the extraction of bleed at the compressor exit ( ${m_{3{\rm{b}},{\rm{corr}}}} \gt $ 0), the operating line shifts towards the choke-line. Thus, the compressor pressure reduces with the extraction of the bleed from the compressor exit. The extraction of air at the compressor exit would reduce the mass flow rate available for the turbine. Hence, the work available for the compressor would reduce, leading to a decrement in the rotor speed. This reduction in rotor speed would cause a decrement in the compressor pressure ratio. The reduction in the pressure ratio combined with a reduction in the mass flow rate through the nozzle leads to thrust decrement, as observed earlier in Fig. 6(b).

In summary, the reduction (or increment) in the fuel flow rate decreases (or increases) the compressor pressure ratio, rotor speed, and thrust. At a given fuel flow rate, the extraction of the bleed at the compressor exit causes a reduction in the compressor pressure ratio, rotor speed and thrust.

4.2 Engine performance during FTV

The objective is to achieve a vector angle ( ${\theta _{\rm{y}}}$ ) of 2.3°, 6.7°, and 7.9°. At ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.83, the vector angles can be achieved by injecting secondary-jet with ${m_{{\rm{s}},{\rm{corr}}}}$ of $2.71 \times {10^{ - 3}}$ , $5.93 \times {10^{ - 3}},$ and $7.15 \times {10^{ - 3}}$ , respectively, obtained from Equation (7) (Fig. 2).

The engine performance during FTV is evaluated for two configurations. In the first configuration, the secondary-jet required for FTV is assumed to be taken from an additional compressor different from the compressor of the turbojet engine chosen for simulation. In the second configuration, the secondary-jet is taken as the bleed from the compressor exit (station 3). The engine response is evaluated by observing the operating point on the compressor map, the thrust magnitude, and the vector angle. During the injection of the secondary-jet, the fuel flow rate can be varied or maintained constant. Hence, two sets of simulations were carried out for each configuration. In the first set of simulations, the fuel flow rate is held constant, termed ‘ ${\dot m_{{\rm{f}},{\rm{const}}}}$ ’, and in the second set of simulations, the fuel flow rate is varied such that the engine rotor speed is kept constant, termed ‘ ${N_{{\rm{const}}}}$ ’.

4.2.1. Without bleed from the compressor

In this configuration, the secondary-jet required for FTV is assumed to be taken from an additional compressor different from the compressor of the turbojet engine. Thus, the bleed option is switched off all through the simulations.

Figure 8 shows the operating points on the compressor map for different ${m_{{\rm{s}},{\rm{corr}}}}$ . The green stars correspond to the operation with a change in throttle (PLA) and no secondary-jet injection ( ${m_{{\rm{s}},{\rm{corr}}}} = 0$ ). The open squares correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = \;2.71 \times {10^{ - 3}}$ and ${N_{{\rm{const}}}}$ . The filled squares correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = \;2.71 \times {10^{ - 3}}$ and ${\dot m_{{\rm{f}},{\rm{const}}}}$ . The open diamonds correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = \;5.93 \times {10^{ - 3}}$ and ${N_{{\rm{const}}}}$ . The filled diamonds correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = 5.93 \times {10^{ - 3}}$ and ${\dot m_{{\rm{f}},{\rm{const}}}}$ . The open triangles correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = \;7.15 \times {10^{ - 3}}$ and ${N_{{\rm{const}}}}$ . The case with constant fuel flow rate ( ${\dot m_{{\rm{f}},{\rm{const}}}}$ ) is discussed first, followed by ${N_{{\rm{const}}}}$ . Before the secondary-jet injection, the operating point is indicated as the ‘starting point’ in the figure. As observed in Fig. 8, after the secondary-jet injection, the operating point shifts to a lower rotor speed resulting in reduced mass flow rate and pressure ratio. This reduction in rotor speed is not due to the decrease in PLA observed earlier in Fig. 6.

Figure 8. Compressor performance map showing operating points during FTV without bleed.

For a converging nozzle assuming isentropic flow, the mass flow rate is given by Equation (17) where ${P_{{\rm{o}}7}}$ in the stagnation pressure at the nozzle inlet, ${T_{07}}$ is the stagnation temperature at the nozzle inlet, ${P_{\rm{a}}}$ is ambient pressure and ${A_8}$ is the nozzle throat area. From Equation (17), the mass flow rate through the nozzle is directly proportional to the nozzle throat area and has a non-linear relationship with the upstream pressure. During FTV, the change in the effective throat area dominates compared to the change in the pressure at the nozzle inlet, thus, reducing the mass flow rate and shifting the operating point to the left. This reduction in the mass flow rate reduces the power available for the turbine reducing the rotor speed and ${{\rm{\pi }}_{\rm{c}}}$ . The overall effect is that the operating point moves closer to the surge line. Thus, compared to a conventional engine, the engine with FTV should have a higher surge margin.

(17) \begin{equation}{\dot m_8} = {P_{\rm{a}}}{A_8}\sqrt {\frac{{2{\rm{\gamma }}}}{{{{R}}{{{T}}_{07}}\left( {{\rm{\gamma }} - 1} \right)}}} \sqrt {{{\left( {\frac{{{P_{{\rm{o}}7}}}}{{{P_{\rm{a}}}}}} \right)}^{\frac{{{\rm{\gamma }} - 1}}{{\rm{\gamma }}}}}\left\{ {{{\left( {\frac{{{P_{{\rm{o}}7}}}}{{{P_{\rm{a}}}}}} \right)}^{\frac{{{\rm{\gamma }} - 1}}{{\rm{\gamma }}}}} - 1} \right\}} \end{equation}

For ${m_{{\rm{s}},{\rm{corr}}}} = \;2.71 \times {10^{ - 3}}$ , the operating point shifts to ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.8, and for ${m_{{\rm{s}},{\rm{corr}}}} = \;5.93 \times {10^{ - 3}}$ , the operating point shifts to ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.62. For ${m_{{\rm{s}},{\rm{corr}}}} = \;7.15 \times {10^{ - 3}}$ , the operating point moved out of the turbine map (operational envelope), and the algorithm did not converge, which is the case of the ‘Not-Converged’ algorithm mentioned in the previous section. It is asserted that, after the injection of the secondary-jet with ${m_{{\rm{s}},{\rm{corr}}}} = \;7.15 \times {10^{ - 3}}$ due to the higher magnitude of reduction in the mass flow rate, the turbine is not able to meet the power required for the compressor leading to unstable operation. At this juncture, it may be concluded that there is an upper limit on the amount of secondary-jet injected into the nozzle for FTV operations for the safe operation of the engine. Now consider the case with ${N_{{\rm{const}}}}$ . For this, the FADEC modifies the fuel flow rate such that the rotor speed is maintained constant. As observed from Fig. 8, during FTV, the operating point shifts towards the surge line on the same speed line, the compressor pressure ratio increases, and the mass flow rate reduces. For ${m_{{\rm{s}},{\rm{corr}}}} = \;2.71 \times {10^{ - 3}}$ , the operating point is closer to the starting point and for ${m_{{\rm{s}},{\rm{corr}}}} = \;5.93 \times {10^{ - 3}}$ and $7.15 \times {10^{ - 3}}$ , the operating point moves closer to the surge line. Thus, with an increase in ${m_{{\rm{s}},{\rm{corr}}}}$ the operating point would shift closer to the surge line reducing the surge margin, which is similar to ${\dot m_{{\rm{f}},{\rm{const}}}}$ case. At this juncture, it may be concluded that the compressor operation shifts towards the surge line during FTV operations. In contrast to ${\dot m_{{\rm{f}},{\rm{const}}}}$ , the algorithm converged for ${m_{{\rm{s}},{\rm{corr}}}} = \;7.15 \times {10^{ - 3}}$ with ${N_{{\rm{const}}}}$ due to the addition of higher energy to the gas by increasing the fuel flow rate. The increment in the fuel flow rate enables the turbine to extract more energy sustaining the engine operation, however, with higher turbine entry temperature (Table 4). Thus, it may be concluded that during FTV, in addition to controlling the flow rate of the secondary-jet, the flow rate of the fuel should also be varied.

Table 3. Vector angle ( ${\theta _{\bf{y}}}$ ) and normalised thrust $\big( {\big| {{{{\vec{\bf T}}}_{\bf{n}}}} \big|} \big)$ at different secondary-jet ( ${{{m}}_{{{s}},{{corr}}}}$ ) without bleed

Table 4. Turbine entry temperature (TET) during FTV at different ${{{m}}_{{{s}},{{corr}}}}$ without bleed

The vector angles ( ${\theta _{\rm{y}}}$ ), thrust magnitudes $\big( {\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big|} \big)$ for all the cases are given in Table 3, and turbine entry temperature (TET) is given in Table 4. At the start of this section, the goal was set to achieve three different vector angles ( ${\theta _{\rm{y}}}$ ) given as ‘desired’ values in Table 3, and the values obtained from simulations are given as ‘obtained’ values. The initial (before FTV) and final (after FTV) values of the normalised thrust $\big( {\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big|} \big)$ are given in Table 3. As observed in the table, for both ${\dot m_{{\rm{f}},{\rm{const}}}}$ and ${N_{{\rm{const}}}}$ , the values of ${\theta _{\rm{y}}}$ obtained during FTV is higher compared to the desired values. The final magnitude of $\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big|$ during FTV is lower compared to the initial value for ${\dot m_{{\rm{f}},{\rm{const}}}}$ , whereas, the final magnitude is higher for ${N_{{\rm{const}}}}$ . For both ${{\dot{m}}_{{\rm{f}},{\rm{const}}}}$ and ${N_{{\rm{const}}}}$ , the difference between the initial (desired) and final (obtained) values increase with an increase in ${m_{{\rm{s}},{\rm{corr}}}}$ . The difference between the desired value (initial) and the obtained (final) value is due to a reduction in the magnitude of ${m_{7,{\rm{corr}}}}$ after the secondary-jet injection. Thus, the actual magnitude of the ${m_{{\rm{s}},{\rm{corr}}}}$ required to achieve a specified vector angle is different from the values estimated from Fig. 2. The actual value of ${m_{{\rm{s}},{\rm{corr}}}}$ can be estimated only by the coupled analysis involving the engine performance with FTV. Another parameter concerning engine safety is the turbine entry temperature (TET). The initial (before FTV) and final (after FTV) values of TET are shown in Table 4. From the table, it may be concluded that the TET is higher during FTV. For ${\dot m_{{\rm{f}},{\rm{const}}}}$ , the increase in the fuel-air ratio is the cause for the rise in TET, whereas for ${N_{{\rm{const}}}}$ the increase in the fuel flow is the cause for the rise in TET.

Figure 9. Compressor performance map showing (a) all operating points (b) zoomed-in view during FTV with bleed.

This set of simulations demonstrates the importance of the coupled analysis involving the engine performance while evaluating the implementation of the FTV. The initial and final values of $\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big|$ and the obtained values of ${\theta _{\rm{y}}}$ can be used to develop the control law for implementing FTV.

3.2.2 With bleed from the compressor

In this configuration, the secondary-jet required for FTV is assumed to be taken from the compressor exit (station 3) of the turbojet engine. Thus, the bleed option is switched on all through the simulations. Since the secondary-jet required for the vectoring is taken from the compressor exit (station 3), ${m_{3{\rm{b}},{\rm{corr}}}} = {m_{{\rm{s}},{\rm{corr}}}}$ . Similar to the previous case, two sets of simulations were carried out, one with “ ${\dot m_{{\rm{f}},{\rm{const}}}}$ ” and the other with ‘ ${N_{{\rm{const}}}}$ ’.

Figure 9(a) shows operating points on the compressor map during FTV with bleed at the compressor exit, and Fig. 9(b) show the zoomed-in view of the same points. Two starting points are indicated, one at ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.83 and the other at ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.91. At ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.83, the simulations did not converge for ${m_{{\rm{s}},{\rm{corr}}}} = \;5.93 \times {10^{ - 3}}$ and ${m_{{\rm{s}},{\rm{corr}}}} = \;7.15 \times {10^{ - 3}}$ with ${\dot m_{{\rm{f}},{\rm{const}}}}$ . Thus, the speed was increased to ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.91, and the simulations for ${m_{{\rm{s}},{\rm{corr}}}} = \;5.93 \times {10^{ - 3}}$ and ${m_{{\rm{s}},{\rm{corr}}}} = \;7.15 \times {10^{ - 3}}$ were repeated with ${\dot m_{{\rm{f}},{\rm{const}}}}$ . The green stars correspond to the operation with the throttle change (PLA) with no secondary-jet injection and no bleed. The open squares correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = \;2.71 \times {10^{ - 3}}$ and ${N_{{\rm{const}}}}$ . The filled squares correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = \;2.71 \times {10^{ - 3}}$ and ${\dot m_{{\rm{f}},{\rm{const}}}}$ . The open diamonds correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = \;5.93 \times {10^{ - 3}}$ , and ${N_{{\rm{const}}}}$ . The open triangles correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = \;7.15 \times {10^{ - 3}}$ , and ${N_{{\rm{const}}}}$ . The filled diamonds correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = 5.93 \times {10^{ - 3}}$ and ${\dot m_{{\rm{f}},{\rm{const}}}}$ . The filled triangles correspond to FTV with ${m_{{\rm{s}},{\rm{corr}}}} = 7.15 \times {10^{ - 3}}$ and ${\dot m_{{\rm{f}},{\rm{const}}}}$ . The starting point for filled diamond and filled square is at ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.91. As observed from Fig. 9(a) or Fig. 9(b), the operating points shifts closer to surge-line during FTV, and the magnitude of shift increases with an increase in the ${m_{{\rm{s}},{\rm{corr}}}}$ . This behaviour is similar to the configuration with no-bleed. However, the magnitude of the shift in the operating point during FTV with bleed is less compared to the case without bleed. The simulations did not converge for ${m_{{\rm{s}},{\rm{corr}}}} = 5.93 \times {10^{ - 3}}$ and $7.15 \times {10^{ - 3}}$ with ${\dot m_{{\rm{f}},{\rm{const}}}}$ . For ${m_{{\rm{s}},{\rm{corr}}}} = 7.15 \times {10^{ - 3}}$ , the simulations did not converge for the case with no-bleed, whereas, for ${m_{{\rm{s}},{\rm{corr}}}} = 5.93 \times {10^{ - 3}}$ , the algorithm converged for the case without bleed, and it did not converge for the case with bleed. This is due to the reduction in the mass flow rate into the turbine after the bleed is extracted at the compressor exit. The reduced mass flow rate flowing through the turbine leads to a decrease in the power available for the compressor, due to which rotor speed decreases continuously, resulting in engine shutdown. After the starting point was moved to ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.91, the mass flow rate through the compressor increases. This additional mass flow rate allows extracting the higher bleed flow of $5.93 \times {10^{ - 3}}$ and $7.15 \times {10^{ - 3}}$ and sufficient mass flow of air is available to the turbine for the successful operation of the engine. Thus, it appears that the bleed extraction may not be suitable for all the operating conditions and may require an additional compressor. This observation further strengthens the earlier finding that the strategy to be adopted for implementing FTV would depend on the operational requirements.

The vector angle ( ${\theta _{\rm{y}}}$ ) and normalised thrust $\big( {\big| {{\overrightarrow{\bf T}_{\bf{n}}}} \big|} \big)$ with the bleed is given in Table 5 for the cases with starting point at ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.83, and in Table 6 for the cases with starting point at ${N_{{\rm{corr}},{\rm{r}}}} = $ 0.91. Similar to the previous case with no-bleed, the vector angle obtained is higher than the desired value for all the cases. The difference in the magnitudes of desired and obtained value increases with an increase in ${m_{{\rm{s}},{\rm{corr}}}}$ . For the case with ${m_{{\rm{s}},{\rm{corr}}}} = 7.15 \times {10^{ - 3}}$ , the obtained value is twice the desired value (Table 7). The final $\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big|$ is lower than the initial value for ${{\dot{m}}_{{\rm{f}},{\rm{const}}}}$ , and final $\big| {{{{\overrightarrow{\bf T}}}_{\bf{n}}}} \big|$ is higher than the initial value for ${{{N}}_{{\rm{const}}}}$ . The magnitude of increase in the thrust for the ${N_{{\rm{const}}}}$ case is small compared to the magnitude of reduction in the thrust for ${\dot m_{{\rm{f}},{\rm{const}}}}$ .

Table 5. Vector angle ( ${\theta}_{\rm {y}}$ ) and normalised thrust $\big( \big| \vec{\bf{T}}_{\bf{n}} \big| \big)$ at different secondary-jet ( ${{m}}_{{{s}},{{corr}}}$ ) with bleed

Table 6. Vector angle ( ${{\bf{\theta }}_{\bf{y}}}$ ) and normalised thrust $\big( {\big| \vec{\bf{T}}_{\bf{n}} \big|} \big)$ at different secondary-jet ( ${{{m}}_{{{s}},{{corr}}}}$ ) with bleed

Table 7. Turbine entry temperature (TET) during FTV at different ${{{m}}_{{{s}},{{corr}}}}$ with bleed

The turbine entry temperatures (TETs) for different test cases are shown in Table 7. The values under the column ‘Initial’ correspond to the starting point, and the column ‘Final’ correspond to the TET during FTV. In both the tables, it is clear that the TET during FTV is higher than the value before FTV. From Tables 4 and 7, it is clear that during FTV operation, the TET increases. Thus, for implementing FTV, the turbine should handle higher flow temperatures. The recent success of implementing ceramic matrix composites [Reference Ohnabe, Masaki, Onozuka, Miyahara and Sasa18] in gas turbines would enable FTV in future aircraft.

4.0 Conclusion

The nozzle performance maps obtained from earlier experiments conducted on a stand-alone converging nozzle to implement FTV using the secondary-jet injection technique are discussed. From these maps, the mathematical relations necessary for the simulations are obtained. The NPR-map resembles the nozzle operation with a reduced throat area, and the magnitude of the change in the effective flow area was estimated from the experimental data. For a given ${{{m}}_{{\rm{s}},{\rm{corr}}}}$ , the magnitude of the change in the effective throat area $\left( {{\rm{\% }}\Delta {A_{{\rm{te}}}}} \right)$ was found to decrease linearly with ${m_{7,{\rm{corr}}}}$ . This ${\rm{\% }}\Delta {A_{{\rm{te}}}}$ is used in performance simulation software (Gasturb 13) using the algorithm developed to study the performance of a single spool turbojet engine during FTV.

Based on the vector angle required, the magnitude of ${m_{{\rm{s}},{\rm{corr}}}}$ is chosen, and corresponding the area reduction (from experimental data) is given as input to the simulation software using the algorithm developed in this work. In the simulations, two configurations were considered based on the source of the secondary-jet. In the first configuration, the secondary-jet is sourced from an additional compressor different from the compressor in the turbojet engine. In the second configuration, the secondary-jet is taken from the compressor exit of the turbojet engine, termed ‘bleed extraction’. In each of the configurations, two sets of simulations were carried out, one while maintaining the throttle constant ( ${\dot m_{{\rm{f}},{\rm{const}}}}$ ) and the other maintaining the rotor speed constant ( ${N_{{\rm{const}}}}$ ).

During FTV, for both the configurations, the engine operation was found to shift towards the surge line, reducing the available surge margin with ${\dot m_{{\rm{f}},{\rm{const}}}}$ and ${N_{{\rm{const}}}}$ . The TET was found to be higher during FTV for both the configurations and with ${\dot m_{{\rm{f}},{\rm{const}}}}$ and ${N_{{\rm{const}}}}$ . Thus, compared to a conventional engine, the engine with FTV should have a higher surge margin and should be able to handle higher TET. For ${\dot m_{{\rm{f}},{\rm{const}}}}$ , the final magnitude of $\big| {{{{\vec{\bf T}}}_{\bf{n}}}} \big|$ is lower compared to the initial value whereas, for ${N_{{\rm{const}}}}$ the final magnitude of $\big| {{{{\vec{\bf T}}}_{\bf{n}}}} \big|$ is higher compared to the initial value. Based on the demand from the flight controls, one of the two ( ${\dot m_{{\rm{f}},{\rm{const}}}}$ or ${N_{{\rm{const}}}}$ ) strategies or a combination of them may be adopted. For both the configurations, the values of ${\theta _{\rm{y}}}$ obtained during FTV is higher compared to the desired values with ${\dot m_{{\rm{f}},{\rm{const}}}}$ and ${N_{{\rm{const}}}}$ . Thus, the magnitude of ${m_{{\rm{s}},{\rm{corr}}}}$ required is different from that expected from the experiments on a stand-alone nozzle. For some test conditions ( ${m_{{\rm{s}},{\rm{corr}}}} = 7.15 \times {10^{ - 3}}$ and without bleed and ${\dot m_{{\rm{f}},{\rm{const}}}}$ ) the turbine operation moves out of its performance map, suggesting that the FTV that can be achieved may be limited based on the engine characteristics. This demonstrates that for evaluating the performance of FTV for an aircraft, the analysis on a stand-alone nozzle is insufficient and should include the coupled analysis.

Footnotes

This paper is a version of a presentation due to be given at the 2022 ISABE Conference

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Figure 0

Figure 1. Components of a single-spool turbojet engine.

Figure 1

Table 1. Values of coefficients in Equation (6) (T-map), Equation (7) (θ-map) and Equation (12) ($\% \Delta {A_{{\bf{te}}}}$) for different ${m_{{{s}},{{corr}}}}$

Figure 2

Figure 2. Nozzle performance maps (a) NPR-map, (b) T-map, and (c) θ-map for the nozzle.

Figure 3

Figure 3. Nozzle throat area change ($\% \Delta {{{A}}_{{\rm{te}}}}$) vs. ${{{m}}_{7,{\rm{corr}}}}$ at different ${{{m}}_{{\rm{s}},{\rm{corr}}}}$.

Figure 4

Figure 4. Schematic showing components and station numbers used.

Figure 5

Table 2. Design point parameters of the turbojet engine chosen for simulation

Figure 6

Figure 5. Algorithm for estimating the response of the engine during fluidic thrust vectoring, (a) flow chart, (b) convergence with the iteration number.

Figure 7

Figure 6. (a) Relative corrected speed (${{{N}}_{{\rm{corr}},{\rm{r}}}}$) vs. fuel flow rate (${{\dot{m}}_{\rm{f}}}$), (b) Normalised thrust from the engine $\big( {\big| {{{{\overrightarrow{\bf T}}}_{{\bf{n}},{\bf{eng}}}}} \big|} \big)$ vs. fuel flow rate (${{\dot{m}}_{\rm{f}}}$), for different bleeds (${{{m}}_{3{\rm{b}},{\rm{corr}}}}$) at compressor exit.

Figure 8

Figure 7. Compressor map showing the engine operating points during engine operation without (${{{m}}_{3{\rm{b}},{\rm{corr}}}} = $ 0) and with bleed (${{{m}}_{3{\rm{b}},{\rm{corr}}}} \gt $ 0).

Figure 9

Figure 8. Compressor performance map showing operating points during FTV without bleed.

Figure 10

Table 3. Vector angle (${\theta _{\bf{y}}}$) and normalised thrust $\big( {\big| {{{{\vec{\bf T}}}_{\bf{n}}}} \big|} \big)$ at different secondary-jet (${{{m}}_{{{s}},{{corr}}}}$) without bleed

Figure 11

Table 4. Turbine entry temperature (TET) during FTV at different ${{{m}}_{{{s}},{{corr}}}}$ without bleed

Figure 12

Figure 9. Compressor performance map showing (a) all operating points (b) zoomed-in view during FTV with bleed.

Figure 13

Table 5. Vector angle (${\theta}_{\rm {y}}$) and normalised thrust $\big( \big| \vec{\bf{T}}_{\bf{n}} \big| \big)$ at different secondary-jet (${{m}}_{{{s}},{{corr}}}$) with bleed

Figure 14

Table 6. Vector angle (${{\bf{\theta }}_{\bf{y}}}$) and normalised thrust $\big( {\big| \vec{\bf{T}}_{\bf{n}} \big|} \big)$ at different secondary-jet (${{{m}}_{{{s}},{{corr}}}}$) with bleed

Figure 15

Table 7. Turbine entry temperature (TET) during FTV at different ${{{m}}_{{{s}},{{corr}}}}$ with bleed