Re-engining of a Mirage F1 Fighter required modification of the existing aircraft refueling system. Aerosud used Flownex to; Predict flow rates and refueling sequences in the system. Investigations of valve failure cases were also performed with Flownex to ensure that for any single failure case, the system would remain safe. |
CUSTOMER PROFILE
Aerosud is a diversified aviation engineering company that provides design, development, prototyping, and in-service support for civil and military aircraft systems. Established in 1990 by key designers of the South African Rooivalk Combat Support Helicopter and leaders from the Cheetah fighter program, Aerosud manufactures around 2,000 parts and assemblies daily for major clients, including Airbus, Boeing, BAE Systems, Agusta Westland Helicopters, and Spirit AeroSystems.
CHALLENGE
A contract which involved the re-engining of a Mirage F1 Fighter with a Klimov RD33 engine used in the Mirage 29 Fighter. Part of the re-engineering required modification of the existing aircraft refuelling system. Aerosud required: prediction of flow rates and refuelling sequences in the system; investigation of valve failure cases to ensure that for any single failure case, the system would remain safe.
BENEFITS
Flownex provided the following benefits:
Simulation of the complete operation of the fuel system and early detection of operational & commissioning issues.
The re-fuelling sequence of the tanks could be optimized to increase the speed of refuelling and improve pilot safety and capital investment protection.
Possibility to test multiple refuelling and valve failure cases.
Graphical representation of the dynamic refuelling sequence.
SOLUTION
The model was used to size tank restrictors and obtain the required flow rates. Refuelling rates were determined to be within the specified envelope. Critical analyses of failure cases were performed. Tank pressures were predicted and vent-lines were analysed at various flow rates to ensure that the aircraft fuel system remains safe and the centre-of-gravity (cg) position of the aircraft remained centred. Aerosud confirmed results predicted by Flownex with ground test results.
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INTRODUCTION
Aerosud, a South African aviation company, had a major contract which involved the re-engining of a Mirage F1 Fighter with a Klimov RD33 engine used in the Mirage 29 Fighter. Part of the re-engineering required modification of the existing aircraft refuelling system. A contract-specified minimum refuelling time resulted in a need for pressure refuelling. As with commercial aircraft, the fundamental need for pressure refuelling of a military aircraft is to provide safe, quick aircraft deployment. There were other safety issues that needed to be considered in the refuelling system of a military aircraft. The fuel system needs to be safely isolated in case of an unsuccessful attempt at in-flight refuelling. Failure of a refuelling system to shutoff can result in hazardous fuel spillage and/or tank over-pressurization which could lead to the loss of an aircraft and/or lives.
Fuel transfer is typically controlled by shutoff valves with associated orifices to control the flow rates into the tanks. These orifices have to be sized appropriately to allow refuelling in the required time frame as well as ensuring that the refuelling sequence is such that the aircraft centre-of-gravity (CG) limits are maintained.
CHALLENGES
Aerosud needed to:
- Predict flow rates and refuelling sequences in the system,
- Investigate valve failure cases and ensure that for any single failure case, the system would remain safe.
BACKGROUND
Aerial refuelling, also called in-flight refuelling, is the process of transferring fuel from one aircraft (the tanker) to another (the receiver) during flight. The procedure allows the receiving aircraft to remain airborne longer, extending its range or loiter time on station. Because the receiver aircraft can be topped up with extra fuel in the air, air refuelling can allow a take-off with a greater payload, which could be weapons, cargo or personnel: the maximum take-off weight is maintained by carrying less fuel and topping up once airborne. Alternatively, a shorter take-off roll can be achieved because take-off can be at a lighter weight before refuelling once airborne.
The F1 fighter has a number of tanks, as shown in Figure 1. Due to the minimum refuelling time required, a pressure refuelling system, in which multiple tanks are refuelled simultaneously, was selected over a traditional method in which the tanks are refuelled individually. Pressure refuelling provides a safe, quick aircraft turnaround time. Typical refuelling pressures are 35 ~ 55 psig (2.41 ~ 3.79 bar g). Based on this operational requirement, it was deemed necessary by Aerosud to model the fuel system.
Figure 2 shows the cheetah fuel system and tank location used on the fighter plane.
The blue lines are the venting/pressurization system, and the yellow lines are the fuel transfer/refuel system. Each tank group consists of its own refuel and transfer valve. Transfer valves are controlled by its associated float valves in each tank group.
SOLUTION
Aerosud modelled the aircraft fuel system in Flownex.
The refuelling system model depicted in Figure 3 is interlinked to the venting system model in Figure 4. This was necessary to model the backpressure of the air being vented out of the fuel tanks and its effect on the refuelling sequence and rate. Transient refuelling operations of the system as well as valve failure cases were simulated.
Changing a restrictor size influences flow rate into a particular tank, which in turn will influence the centre-of-gravity (cg) position of the aircraft. Thus the need to model the change in cg position as the tanks fill.
Figure 6 and Figure 7 and show tools available within Flownex to display results. An HMI was developed to display the tank levels and flow rates and the tanks pressures could be shown on a graph.
The pressure spikes in Figure 6 caused by the opening and closing valves were also observed on transient ground tests.
BENEFITS OF USING FLOWNEX
A Human User Interface (HMI) to simplify the use of the constructed model and to help with visual interpretation of results could be developed. See Figure 5 and Figure 7.
Pressure in the different tanks could be displayed graphically during the refuelling sequence to identify possible operational issues and to determine the maximum pressure operational envelope. See Figure 6.
The piping data could be obtained from the built-in pipe schedule tables to speed up the creation time of the model. This allowed the engineering team to spend more time in evaluating and improving the results of the design changes.
Full operation of the fuel system could be simulated. Thus, commissioning and operational issues could be detected early and rectified even before the actual ground and eventually air refuelling commissioning. This greatly reduced commissioning time and saved Aerosud precious time & money.
The re-fuelling sequence of the tanks could be optimized to increase the speed of refuelling and improve pilot safety and capital investment protection.
The adequacy of the venting/pressurization system was also tested.
Several re-fuelling and valve failure cases could be saved as scenarios within the model, which can be re-called at any time for further simulations and refinements.
RESULTS AND CONCLUSION
Flownex provided adequate information on the fuel system which assisted the engineers during the design and development phase with reasonable accuracy. The model was used to size the restrictors to the tanks in order to obtain the required flow rates. Refuelling times were also determined to be within specified minimum times. The critical analysis of failure cases was performed. Tank pressures were predicted and vent-lines were analyzed at various flow rates. This was to ensure that the aircraft fuel system remains safe and the centre-of-gravity (cg) position of the aircraft remains in the centre. Aerosud was able to corroborate the results predicted by Flownex with results from ground tests.