Follow-up Study on Verification Methods for Corrosion Prevention and Control of US Military Aviation Equipment

LI Ming; YANG Zhaojun; ZHANG Lei; XING Zhaojun; FU Yun

doi:10.7643/issn.1672-9242.2026.03.001

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Equipment Environmental Engineering ›› 2026, Vol. 23 ›› Issue (3) : 1-9. DOI: 10.7643/issn.1672-9242.2026.03.001

Special Issue—Equipment Service Environment and Performance Testing

Follow-up Study on Verification Methods for Corrosion Prevention and Control of US Military Aviation Equipment

LI Ming¹, YANG Zhaojun¹, ZHANG Lei², XING Zhaojun², FU Yun^1,*

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Abstract

The work aims to systematically analyze the main development process and future direction of the verification methods for corrosion prevention and control of US military aviation equipment from modes, methods and technology, and propose suggestions for the verification work for corrosion prevention and control of Chinese aviation equipment. Firstly, three modes in the verification for corrosion prevention and control experienced by US military aviation equipment are reviewed and summarized, and the verification requirements, verification contents and main characteristics of different verification modes are analyzed. Secondly, the basic framework, design concepts, main advantages and related requirements of building-block verification for corrosion prevention and control are analyzed in combination with the latest requirements of verification for corrosion prevention and control of US military equipment and the latest revisions of the relevant technical content of MIL-STD-810H. Finally, the development trends, development priorities and technical characteristics of the verification technology for corrosion prevention and control of US military equipment are analyzed from two aspects: laboratory corrosion tests and digital verification by practical examples. Through a systematic review and comparative analysis of verification methods for corrosion prevention and control of US military aviation equipment, the inherent logic behind the evolution of corrosion prevention and control verification from a single test to a systematic verification throughout the entire life cycle is revealed. This insight can provide a reference for establishing a verification and evaluation system of corrosion prevention and control that meets the demands of the future battlefield and aligns with the development characteristics of Chinese aviation equipment.

Key words

aviation equipment / entire life cycle / verification for corrosion prevention and control / corrosion test / building-block verification / digital verification

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LI Ming, YANG Zhaojun, ZHANG Lei, XING Zhaojun, FU Yun. Follow-up Study on Verification Methods for Corrosion Prevention and Control of US Military Aviation Equipment[J]. Equipment Environmental Engineering. 2026, 23(3): 1-9 https://doi.org/10.7643/issn.1672-9242.2026.03.001

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