仪器仪表和飞机前缘温度自动控制

S. Finlayson, G. S. Gupta
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引用次数: 3

摘要

飞机在20,000英尺以上的高空飞行过程中,环境条件可能导致飞机控制表面结冰,低于-40°C的极端温度是一个很大的因素。老式飞机的防冰系统主要是利用热发动机引气来调节飞机控制表面的温度。新西兰皇家空军(RNZAF) P-3K猎户座飞机采用手动激活控制系统来控制和监测前沿防结冰要求。这种手动激活的系统变得越来越不可靠和难以维护,机组人员需要手动激活控制电路,在某些情况下需要持续监控。本文讨论了一种应用模糊逻辑控制电路来控制流量控制阀的自动化解决方案,从而调节通过翼腔的引气量。该系统的控制由一个混合信号现场可编程微控制器Silicon Laboratories C8051F020提供。引气流量的自动调节在所需的设定点上提供温度稳定性。该解决方案减少了机组人员的互动,实现了对发动机引气的有效控制,并为用户提供了额外的数据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Instrumentation and automated control of aircraft leading edge temperature
During the process of flying an aircraft at an altitude in excess of 20,000ft, environmental conditions can lead to ice being accumulated on the control surfaces of the aircraft with temperature extremes that are lower than -40°C being a large contributing factor. Anti-icing systems in dated aircraft predominantly apply hot engine bleed air to regulate the temperature on the aircraft control surfaces. The Royal New Zealand Air force (RNZAF) P-3K Orion aircraft utilizes a manually activated control system for controlling and monitoring the leading edge anti icing requirements. This manually activated system is becoming unreliable and difficult to maintain, the aircrew are required to manually activate the control circuit and in some instances constant monitoring is required. This paper discusses an automated solution that applies a fuzzy logic control circuit to control flow control valves which in turn regulate the amount of bleed air passed through a wing cavity. The control for the system is provided by a mixed-signal field programmable microcontroller, the Silicon Laboratories C8051F020. Automatic regulation of the bleed air flow provides temperature stability at the required set point. This solution reduces the aircrew interaction, achieves efficient control of the engine bleed air, and provides additional data to the user.
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