Low-Thrust Solid Rocket Motors for Small, Fast Aircraft Propulsion: Design and Development

Small, low-thrust, long-burn-time solid propellant rocket motors could provide propulsion for a new class of kilogram-scale, transonic, uncrewed aerial vehicles (UAVs). This paper investigates technological challenges of small, low-thrust solid rocket motors: slow-burn solid propellants, motors that...

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Veröffentlicht in:	Journal of propulsion and power 2022, Vol.38 (1), p.122-134
Hauptverfasser:	Vernacchia, Matthew T, Mathesius, Kelly J, Hansman, R. John
Format:	Artikel
Sprache:	eng
Schlagworte:	Ablation Aeronautics Aircraft Aircraft design Aircraft propulsion Aircraft rockets Ammonium perchlorates Design Heat conductivity Low thrust Motors Nozzles Reynolds number Rockets Solid propellant rocket engines Solid propellants Thermal protection Unmanned aerial vehicles
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container_title	Journal of propulsion and power
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creator	Vernacchia, Matthew T Mathesius, Kelly J Hansman, R. John
description	Small, low-thrust, long-burn-time solid propellant rocket motors could provide propulsion for a new class of kilogram-scale, transonic, uncrewed aerial vehicles (UAVs). This paper investigates technological challenges of small, low-thrust solid rocket motors: slow-burn solid propellants, motors that have low thrust relative to their size (and thus have low chamber pressure), thermal protection for the motor case, and small nozzles that can withstand long burn times. Slow-burn propellants were developed using ammonium perchlorate and 0–20% oxamide (burn-rate suppressant), with burn rates of 1–4 mm⋅s−1 at 1 MPa. Using these propellants, a low-thrust motor successfully operated at a thrust/burn area ratio 10 times less than that of typical solid rocket motors. This kilogram-scale motor can provide 5–10 N of thrust for 1–3 min. An ablative thermal protection liner was tested in these firings, and a new ceramic-insulated nozzle was demonstrated. This paper shows that small, low-thrust solid motors are feasible and presents a baseline design for the integration of such a motor into a small UAV.
doi_str_mv	10.2514/1.B38104
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John</creator><creatorcontrib>Vernacchia, Matthew T ; Mathesius, Kelly J ; Hansman, R. John</creatorcontrib><description>Small, low-thrust, long-burn-time solid propellant rocket motors could provide propulsion for a new class of kilogram-scale, transonic, uncrewed aerial vehicles (UAVs). This paper investigates technological challenges of small, low-thrust solid rocket motors: slow-burn solid propellants, motors that have low thrust relative to their size (and thus have low chamber pressure), thermal protection for the motor case, and small nozzles that can withstand long burn times. Slow-burn propellants were developed using ammonium perchlorate and 0–20% oxamide (burn-rate suppressant), with burn rates of 1–4 mm⋅s−1 at 1 MPa. Using these propellants, a low-thrust motor successfully operated at a thrust/burn area ratio 10 times less than that of typical solid rocket motors. This kilogram-scale motor can provide 5–10 N of thrust for 1–3 min. An ablative thermal protection liner was tested in these firings, and a new ceramic-insulated nozzle was demonstrated. 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John</creatorcontrib><title>Low-Thrust Solid Rocket Motors for Small, Fast Aircraft Propulsion: Design and Development</title><title>Journal of propulsion and power</title><description>Small, low-thrust, long-burn-time solid propellant rocket motors could provide propulsion for a new class of kilogram-scale, transonic, uncrewed aerial vehicles (UAVs). This paper investigates technological challenges of small, low-thrust solid rocket motors: slow-burn solid propellants, motors that have low thrust relative to their size (and thus have low chamber pressure), thermal protection for the motor case, and small nozzles that can withstand long burn times. Slow-burn propellants were developed using ammonium perchlorate and 0–20% oxamide (burn-rate suppressant), with burn rates of 1–4 mm⋅s−1 at 1 MPa. Using these propellants, a low-thrust motor successfully operated at a thrust/burn area ratio 10 times less than that of typical solid rocket motors. This kilogram-scale motor can provide 5–10 N of thrust for 1–3 min. An ablative thermal protection liner was tested in these firings, and a new ceramic-insulated nozzle was demonstrated. This paper shows that small, low-thrust solid motors are feasible and presents a baseline design for the integration of such a motor into a small UAV.</description><subject>Ablation</subject><subject>Aeronautics</subject><subject>Aircraft</subject><subject>Aircraft design</subject><subject>Aircraft propulsion</subject><subject>Aircraft rockets</subject><subject>Ammonium perchlorates</subject><subject>Design</subject><subject>Heat conductivity</subject><subject>Low thrust</subject><subject>Motors</subject><subject>Nozzles</subject><subject>Reynolds number</subject><subject>Rockets</subject><subject>Solid propellant rocket engines</subject><subject>Solid propellants</subject><subject>Thermal protection</subject><subject>Unmanned aerial vehicles</subject><issn>1533-3876</issn><issn>0748-4658</issn><issn>1533-3876</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2022</creationdate><recordtype>article</recordtype><recordid>eNpl0EFLwzAUB_AgCs4p-BECIniwM69pm8zbnE6FieJ68hLSJNXOrqlJqvjtrVRQ8PT-hx__x3sIHQKZxCkkZzC5oBxIsoVGkFIaUc6y7T95F-15vyYEMp6xEXpa2o8of3GdD3hl60rjR6teTcB3NljncWkdXm1kXZ_ihezNrHLKyTLgB2fbrvaVbc7xpfHVc4Nlo_v4bmrbbkwT9tFOKWtvDn7mGOWLq3x-Ey3vr2_ns2UkKUxDxEhCITOSkhhIxkypDSQFUZoTo4BxrqQuVBGTckpjA6qUWmeKsIKxNJacjtHRUNs6-9YZH8Tadq7pN4o4A54y3t_aq5NBKWe9d6YUras20n0KIOL7cQLE8LieHg9UVlL-lv1zX46CavU</recordid><startdate>2022</startdate><enddate>2022</enddate><creator>Vernacchia, Matthew T</creator><creator>Mathesius, Kelly J</creator><creator>Hansman, R. 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subjects	Ablation Aeronautics Aircraft Aircraft design Aircraft propulsion Aircraft rockets Ammonium perchlorates Design Heat conductivity Low thrust Motors Nozzles Reynolds number Rockets Solid propellant rocket engines Solid propellants Thermal protection Unmanned aerial vehicles
title	Low-Thrust Solid Rocket Motors for Small, Fast Aircraft Propulsion: Design and Development
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