Investigation of axial-injection end-burning hybrid rocket motor regression

Saito, Yuji;Yokoi, Toshiki;Neumann, Lukas;Yasukochi, Hiroyuki;Soeda, Kentaro;Totani, Tsuyoshi;Wakita, Masashi;Nagata, Harunori;

doi:10.12989/aas.2017.4.3.281

Advances in aircraft and spacecraft science

Volume 4 Issue 3
/
Pages.281-296
/
2017
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2287-528X(pISSN)
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2287-5271(eISSN)

Techno-Press (테크노프레스)

DOI QR Code

Investigation of axial-injection end-burning hybrid rocket motor regression

Saito, Yuji (Graduate school of Engineering, Hokkaido University) ;
Yokoi, Toshiki (Graduate school of Engineering, Hokkaido University) ;
Neumann, Lukas (Faculty of Engineering, Technical University of Berlin,) ;
Yasukochi, Hiroyuki (Institute for Photon Science and Technology, The University of Tokyo) ;
Soeda, Kentaro (Institute for Photon Science and Technology, The University of Tokyo) ;
Totani, Tsuyoshi (Faculty of Engineering, Hokkaido University) ;
Wakita, Masashi (Faculty of Engineering, Hokkaido University) ;
Nagata, Harunori (Faculty of Engineering, Hokkaido University)

Received : 2016.03.31
Accepted : 2016.09.13
Published : 2017.05.25

https://doi.org/10.12989/aas.2017.4.3.281 Citation KSCI

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Abstract

The axial-injection end-burning hybrid rocket proposed twenty years ago by the authors recently recaptured the attention of researchers for its virtues such as no ${\zeta}$ (oxidizer to fuel mass ratio) shift during firing and good throttling characteristics. This paper is the first report verifying these virtues using a laboratory scale motor. There are several requirements for realizing this type of hybrid rocket: 1) high fuel filling rate for obtaining an optimal ${\zeta}$; 2) small port intervals for increasing port merging rate; 3) ports arrayed across the entire fuel section. Because these requirements could not be satisfied by common manufacturing methods, no previous researchers have conducted experiments with this kind of hybrid rocket. Recent advances in high accuracy 3D printing now allow for fuel to be produced that meets these three requirements. The fuel grains used in this study were produced by a high precision light polymerized 3D printer. Each grain consisted of an array of 0.3 mm diameter ports for a fuel filling rate of 98% .The authors conducted several firing tests with various oxidizer mass flow rates and chamber pressures, and analysed the results, including ${\zeta}$ history, using a new reconstruction technique. The results show that ${\zeta}$ remains almost constant throughout tests of varying oxidizer mass flow rates, and that regression rate in the axial direction is a nearly linear function of chamber pressure with a pressure exponent of 0.996.

Keywords

Acknowledgement

Supported by : Ministry of Education, Science, Sports and Culture

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