الزامات و معیارهای انتخاب مواد فلزی و کامپوزیتی برای ساخت بدنه مخازن کرایوژنیک در پرتابگرهای روز دنیا

جعفری, مهدی; کاوه, امیر; دلیر, مهدی; رسولی, مهرداد; جعفری, حسین

doi:10.22034/jtae.2025.9.2.6

الزامات و معیارهای انتخاب مواد فلزی و کامپوزیتی برای ساخت بدنه مخازن کرایوژنیک در پرتابگرهای روز دنیا

نوع مقاله : علمی- ترویجی

نویسندگان

مهدی جعفری ¹

امیر کاوه ²

مهدی دلیر ³

مهرداد رسولی ⁴

حسین جعفری ⁵

¹ دانشیار، دانشکده مهندسی هوافضا، دانشگاه صنعتی مالک اشتر، تهران، ایران

² استادیار، مجتمع دانشگاهی مواد و فناوری‌های ساخت، دانشگاه صنعتی مالک اشتر، تهران، ایران

³ کارشناس ارشد مهندسی مواد، دانشکده مهندسی مواد و متالورژی، دانشگاه تهران، تهران

⁴ کارشناس ارشد، دانشکده مهندسی شیمی نساجی- علوم الیاف، دانشگاه آزاد اسلامی علوم تحقیقات، تهران

⁵ دانشجوی دکترا، مجتمع دانشگاهی مواد و فناوریهای ساخت، دانشگاه صنعتی مالک اشتر، تهران

10.22034/jtae.2025.9.2.6

چکیده

پرتابگرهای مدرن از سوخت‌های مایع مانند هیدروژن و اکسیژن مایع در دماهای کرایوژنیک استفاده می‌کنند. مخازن کرایوژنیک برای ذخیره‌سازی و حمل‌ونقل هیدروژن مایع، که به دلیل دمای بسیار پایین (20 کلوین) چالش‌برانگیز است، نقش کلیدی دارند. مواد مورد استفاده باید دارای ویژگی‌هایی از جمله سازگاری با محیط هیدروژن مایع، مقاومت در برابر تردی هیدروژنی و خواص مکانیکی و ترموفیزیکی مناسب باشند. این ویژگی‌ها به طراحی ایمن و قابل‌اعتماد مخازن کمک می‌کنند. در این گزارش، انواع مواد کرایوژنیک مورد استفاده در مخازن هیدروژن مایع، پیشرفت‌های تحقیقاتی، داده‌های عملکرد در دماهای پایین و نواقص موجود بررسی شده است. فولاد ضدزنگ رایج‌ترین ماده مورد استفاده است، اما تحقیقات در مورد مواد با استحکام بالا مانند آلیاژهای آلومینیوم و تیتانیوم و مواد کامپوزیتی در حال توسعه است. استفاده از مخازن کامپوزیتی، مانند آنچه در پرتابگرهای DC-XA، X-33 و SpaceX به کار رفته، می‌تواند وزن مخازن را تا 18% کاهش دهد.

کلیدواژه‌ها

مخازن کرایوژنیک

بدنه سوخت پرتابگر

ذخیره‌سازی هیدروژن مایع

مخازن کامپوزیتی کرایوژنیک

موضوعات

سازه‌/مکانیک جامدات/دینامیک جامدات/ارتعاشات/آئروالاستیسیته/...

عنوان مقاله English

Requirements and Criteria for Selecting Metallic and Composite Materials for Cryogenic Tank Structures in Modern Launch Vehicles

نویسندگان English

Mehdi jafari ¹

Amir Kaveh ²

Mehdi Dalir ³

mehrdad rasouli ⁴

hosain jafari ⁵

¹ Faculty of Aerospace, Malek Ashtar University of Technology, Tehran, Iran

² Faculty of Aerospace, Malek Ashtar University of Technology, Tehran, Iran

³ School of Metallurgy and Materials Engineering, University of Tehran, Tehran, Iran

⁴ Faculty of Textile Chemical Engineering - Fiber Science, Islamic Azad University of Research Sciences, Tehran, Iran

⁵ Materials and Manufacturing Technology Faculty, Malek Ashtar University of Technology, Tehran, Iran

چکیده English

Modern launch vehicles depend on liquid fuels such as liquid hydrogen and oxygen, which must be stored at cryogenic temperatures. Cryogenic tanks are essential for containing and transporting liquid hydrogen and serve as critical infrastructure across the defense, aerospace, and energy sectors. Given the extremely low boiling point of liquid hydrogen (20 K), materials used for these tanks must meet stringent requirements, including chemical compatibility with hydrogen, resistance to hydrogen embrittlement, and reliable mechanical and thermophysical performance at cryogenic temperatures. These characteristics are vital to ensuring structural integrity and operational reliability. This report provides a detailed evaluation of cryogenic materials currently used to store and transport liquid hydrogen. It reviews recent research advances, compiles performance data under low-temperature conditions, and identifies key material characterization and application gaps. The objective is to support informed material selection for future cryogenic tank development. Stainless steel remains the most widely used material for liquid hydrogen storage, with different grades selected based on specific operational demands. However, the growing need for space-based hydrogen systems has accelerated research into advanced cryogenic materials, including high-strength aluminum alloys, titanium alloys, and composite structures. Composite cryogenic tanks have been implemented in launch vehicles such as the DC-XA, X-33, and various platforms developed by SpaceX and in programs led by McDonnell Douglas and Lockheed Martin (LM). Notably, LM reported up to an 18% weight reduction by replacing metallic tanks with composite alternatives. This review critically evaluates cryogenic tank materials' applicability to next-generation launch vehicle designs.

کلیدواژه‌ها English

Cryogenic tanks

rocket engine fuel

liquid hydrogen storage

composite cryogenic tanks

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