Abstract

The new requirement of installing the flight stabilization system onboard the airplanes for performing the single-pilot flights in IFR rules was issued lately. It caused the necessity of developing such a system for small aircraft. The proposed system was developed using Model-Based Design then tuned and tested in Model, Pilot and Hardware in the Loop Simulations. The paper presents the next advanced stage of testing—verification in simulation and ground tests on the PZL-130 Orlik airplane. The implementation of this system does not modify the pilot’s primary manual controls. The newly introduced electrical trim is used for automatic stabilization but can be used at manual trimming as it was previously, depending on the chosen operation mode. The ground tests were planned according to civil aviation authority and aviation law requirements. Chosen results from simulated flights were analyzed and presented, confirming the effectiveness of the proposed system. The dedicated application allowing the test engineer to change stabilization system parameters during the flight on a touchscreen tablet was developed and described. The outcome of the stabilization system test campaign was a verification of its performance before the flight tests. The comparison of simulated and real flight data will allow identifying model deficiencies and flight stabilization system efficiency, which makes possible improvements implementation. Additionally, it appeared to be the cost-effective and less electrical energy-consuming automatic flight stabilization system for small aircraft. Such features benefit initiatives like Future Sky, More Electric Aircraft and aircraft stabilization system retrofit.

Highlights

  • The slipstream effect became evident during World War II after introducing piston engines and again in the 1970s when propeller-powered civil purpose airplanes were equipped with turbine engines

  • The PZL-130 TC-II Orlik airplane, earlier classified as Good according to Cooper–Harper rating scale [1], after the engine replacement was degraded to Fair

  • The flight stabilization system designing process was initiated with the extensive analyses of requirements for the system functionalities and specifications of the airplane’s operational capabilities, onboard systems and civil and military standards related to such systems

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Summary

Introduction

The slipstream effect became evident during World War II after introducing piston engines and again in the 1970s when propeller-powered civil purpose airplanes were equipped with turbine engines. The team of engineers from the Institute of Aviation in Warsaw commenced the development of an automatic rudder trimming system [2] aiming at yaw compensation induced by slipstream effects As a result, it was developed, built on the airplane and substantially improved its piloting characteristics. The trimming system is mechanically less complex, and it does not require of the main control surfaces, which change the forces felt by the pilot on the joystick and any switching mechanisms or overload clutch engaged in the case of actuator lockage. The flight stabilization system designing process was initiated with the extensive analyses of requirements for the system functionalities and specifications of the airplane’s operational capabilities, onboard systems and civil and military standards related to such systems. What is noticeable from the pilot’s point of view is that when the crew takes back control, the aircraft is properly trimmed, allowing for an easy transition

Initial Verification of the Assumed Hypothesis
Model-Based Design
Pre-Flight Simulation Results
Installation on Aircraft and Ground Tests
Conclusions and Final Remarks

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