Multidisciplinary Innovations and Research in Applied Engineering
Vol. 2 No. 2 (2025)

Design, Kinematic Analysis, and Scaled Prototype Validation of a Pneumatic Ejection Mechanism for Supersonic Re-Entry Capsule Testing

Alfan Firmansyah Aditya Aditya (Akademi Inovasi Indonesia)
Bagus Wicaksono (Unknown)
Akhmad Mukhlisin (Akademi Inovasi Indonesia)
Nur Hadi Ardiyanto (Akademi Inovasi Indonesia)
Rajni Rizkia Sirat (Unknown)
Muhammad Rafi Akbar Salahudin (Unknown)
Afzalurrohman Abdullah (Unknown)
Alfin Mardiansyah (Akademi Inovasi Indonesia)
Muchammad Rifki Sistiawan (Unknown)
Rajib Alamsyah (Akademi Inovasi Indonesia)
Rahmat Dani Sulistyo (Unknown)
Ade Firmansyah (Akademi Inovasi Indonesia)
Luthfy Iqbal Musthofa (Akademi Inovasi Indonesia)
Yoga Aditiya Dwi Syah Putra (Akademi Inovasi Indonesia)
Ahmad Yusuf Maulana (Akademi Inovasi Indonesia)
Pandu Priyo Jatmiko (Akademi Inovasi Indonesia)
Muhammad Thoriq Akmal Aliansyah (Akademi Inovasi Indonesia)
Johnson Fernando (Akademi Inovasi Indonesia)
Prayogi Dwi Kuncoro (Akademi Inovasi Indonesia)
Diah Ayu Suci Kinasih (Akademi Inovasi Indonesia)
Fajrul Falah (Akademi Inovasi Indonesia)



Article Info

Publish Date
31 Dec 2025

Abstract

High-altitude free-flight tests require release mechanisms capable of placing sub-scale re-entry capsules into a clean supersonic freestream while minimizing wake-induced attitude perturbations. This study presents AERO, a compact pneumatic ejection mechanism developed to support NASA SPEED-class capsule-release requirements as a scientific contribution to re-entry testing technology. The method combined wake-clearance interpretation, first-order kinematic sizing, pneumatic force analysis, CAD-based packaging, manufacturability assessment, and scaled prototype testing. A two-projectile-length clearance distance of 1.33 m was adopted, giving a required initial velocity of 5.11 m/s for a 0.5 s separation target. The full-scale analytical model predicted an ejection velocity of 5.2 m/s and a 0.44 s separation time at 0.5 MPa; increasing the operating pressure to 1.5 MPa increased the velocity to 9.7 m/s and reduced the separation time to 0.15 s. A 30% scale prototype using a 32 g Genesis Firefly capsule model showed a pressure-dependent height response, increasing from 63.0 cm at 0.2 MPa to 136.8 cm at 0.6 MPa. These findings provide analytical and scaled-prototype evidence that a pressure-tunable pneumatic architecture with a balancing hugger can support rapid, repeatable, and geometry-adaptable capsule ejection; flight-representative performance remains to be validated.

Copyrights © 2025






Journal Info

Abbrev

mirae

Publisher

Subject

Computer Science & IT Electrical & Electronics Engineering Engineering Industrial & Manufacturing Engineering Materials Science & Nanotechnology Mechanical Engineering

Description

MIRAE Journal is dedicated to publishing innovative research and reviews in science and technology. We focus on mechanical engineering and product design, industrial and manufacturing engineering, electrical and electronics engineering, computer science and engineering, biomedical engineering, ...