Long wave infrared signature of swept back leading edges in aircraft frontal aspect

IF 1.2 4区工程技术 Q3 ENGINEERING, AEROSPACE Aircraft Engineering and Aerospace Technology Pub Date : 2024-01-18 DOI:10.1108/aeat-02-2023-0056

Kajal Vinayak, Shripad P. Mahulikar

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Abstract

Purpose

In recent years, increased use of all-aspect infrared (IR)-guided missiles based on the long-wave infrared (LWIR; 8–12 µm) band has lowered the probability of aircraft survival in warfare. The lock-on of these highly sensitive missiles is difficult to break, especially from the front. Aerodynamically heated swept-back leading edges (SBLE), because of their high temperature and large area, serve as a prominent LWIR source for aircraft detection from the front. This study aims to report the influence of sweep-back angle (Λ, based on the Mach number [M_∞]) on aerodynamic heating and the LWIR signature of SBLE.

Design/methodology/approach

The temperature along SBLE is obtained numerically as radiation equilibrium temperature (T_w) by discretizing the SBLE length into “n” number of segments, and for each segment, emission based on T_w is evaluated. IR radiance due to reflected external sources (sky-shine and Earthshine) and radiance due to T_w are collectively used to determine the IR contrast between SBLE and its replaced background in the LWIR band (i_{cont-SBLE,LWIR}).

Findings

The results are obtained for low subsonic turboprop aircraft (Λ = 3°, M_∞ = 0.44); high subsonic strategic bombers (Λ = 35°, M_∞ = 0.8); fifth-generation stealth aircraft (Λ = 40°, M_∞ = 1.6); and aircraft with supercruise/supersonic capability (Λ = 50°, M_∞ = 2.5). The aircraft with supersonic capability (Λ = 50°, M_∞ = 2.5) reports the maximum LWIR signatures and hence the highest visibility from the front. The results obtained are compared with values at Λ = 0° for all cases, which shows that increasing Λ significantly reduces aerodynamic heating and LWIR signatures.

Originality/value

The novelty of this study comes from its report on the influence of Λ on the LWIR signatures of aircraft SBLE in the frontal aspect for the first time.

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飞机正面后掠前缘的长波红外特征

目的近年来，基于长波红外（LWIR；8-12 µm）波段的全谱段红外制导导弹的使用日益增多，降低了飞机在战争中的生存概率。这些高灵敏度导弹的锁定功能很难打破，尤其是从正面。空气动力学加热的后掠前缘（SBLE）由于温度高、面积大，成为从正面探测飞机的一个突出的 LWIR 信号源。本研究旨在报告后掠角（Λ，基于马赫数 [M∞]）对气动加热和 SBLE 的近红外特征的影响。设计/方法/途径通过将 SBLE 长度离散为 "n "段，以数值方式获得 SBLE 沿线的温度，即辐射平衡温度（Tw），并根据 Tw 对每一段的辐射进行评估。外部反射源（天光和地光）引起的红外辐射度和 Tw 引起的辐射度共同用于确定 SBLE 与其在 LWIR 波段被替换背景之间的红外对比度（icont-SBLE,LWIR）。研究结果低亚音速涡轮螺旋桨飞机（Λ = 3°，M∞ = 0.44）；高亚音速战略轰炸机（Λ = 35°，M∞ = 0.8）；第五代隐形飞机（Λ = 40°，M∞ = 1.6）；以及具有超巡航/超音速能力的飞机（Λ = 50°，M∞ = 2.5）。具有超音速能力的飞机（Λ = 50°，M∞ = 2.5）具有最大的长波红外特征，因此从前方的能见度最高。在所有情况下，所获得的结果都与 Λ = 0° 时的值进行了比较，结果表明，增加 Λ 可以显著减少气动加热和低温红外特征。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Aircraft Engineering and Aerospace Technology 工程技术-工程：宇航

CiteScore

3.20

自引率

13.30%

发文量

168

审稿时长

8 months

期刊介绍： Aircraft Engineering and Aerospace Technology provides a broad coverage of the materials and techniques employed in the aircraft and aerospace industry. Its international perspectives allow readers to keep up to date with current thinking and developments in critical areas such as coping with increasingly overcrowded airways, the development of new materials, recent breakthroughs in navigation technology - and more.