德留 真一郎

The Institute of Space and Astronautical Science (ISAS) of the Japan Aerospace Exploration Agency (JAXA) conducts a deep space exploration mission named Demonstration and Experiment of Space Technology for INterplanetary voYage with Phaethon fLyby and dUst Science (DESTINY+). The mission requires a high-performance, compact solid kick stage with a high mass ratio and high system safety. The kick stage employes a newly developed laser ignition system to meet these requirements. We designed a laser unit for upper stages (LUUS), two types of laser-initiated pyrotechnic devices for solid motor ignition and a separation device actuator (the LID and LCTG) for the kick stage system. Optical fiber paths connecting the LUUS to LID/LCTG enables a continuity check by optical frequency domain reflectometry (OFDR). We successfully conducted continuity checks with OFDR and ran laser ignition tests to validate the design in simulating assembly- and launchsite operations.

Laser-initiated ignition systems (LIISs) have been developed with the aim of providing essential immunity to electrical disturbances. In the basic configurations of such systems, the electric circuits for generating the laser and detonator signals are electrically separated by a non-conductive optical fiber, increasing the resistance to ignition stimuli other than laser light on the detonator side. In this study, the various environmental resistance tests required for the detonators currently used in rockets were conducted for a new laser-initiated detonator (LID). As all of the tests show results satisfying the requirements, it is considered that the LID has reached the stage of practical use.

Highlights • Strategy formulated under Inter-University Research Institute System unique to Japan. • To develop a competitive space transportation system by using advanced technologies. • To “start small” for fulfilling our target to achieve innovations in human society. • “Fusion of transportation with exploration” in deep space exploration missions. • “Small flying test bed system” to conduct flying technology demonstrations. Abstract The Space Transportation System Committee of the Institute of Space and Astronautical Science (ISAS) of the Japan Aerospace Exploration Agency (JAXA) has been continuously formulating medium-to long-term strategies in the field of space transportation systems under the Inter-University Research Institute System of ISAS since FY2018. This committee is considering the role of ISAS in cooperation with the organization-wide activities of JAXA to formulate strategies in the field of space transportation systems. Among its previous achievements, the committee assembled a strategic target and scenario for the space transportation system research field at the end of FY2018 and has been continuously revising it. Based on the formulated mission scenario, the committee identified three priority areas related to system technologies that must be tackled. These are a “reusable orbit transportation system” aimed for highly frequent mass transportation from Earth to low Earth orbits, “deep space interorbital transportation system” aimed for a marked improvement in space science and exploration missions in terms of frequency and flexibility, and “small flying test bed system” for flight demonstrations, which is indispensable in the research and development of space transportation systems. In this paper, the authors summarize the medium-to long-term strategies and their concrete implementation measures over the next two decades. Keywords Strategic R&D, Space transportation system, Deep space exploration, Small flying test bed, Start small

In order to use laser ignition systems for solid rocket motors operating in deep space environments, it is necessary to elucidate the laser ignition characteristics of the ignition charge in low-temperature environments. This study aims to design an experimental system that can confirm the ignition threshold, ignition delay, and ignition temperature by irradiating an ignition charge with a diode laser in a low-temperature environment. Ignition experiments at room temperature were conducted. The data were evaluated statistically to obtain an ignition threshold with the maximum likelihood method. The relationship between the laser irradiation duration and the laser power with respect to the ignition threshold was obtained. The target value of the low-temperature environment temperature was determined as -50 °C. We examined the requirements of the experimental system and conceptually designed the system to simulate the low-temperature environment. It was confirmed that the constructed experimental system cooled the ignition charge to -50 °C. In the ignition experiment, the ignition charge was successfully ignited at room temperature and at low temperature. The ignition delay, the ignition temperature, and the high-speed image were obtained. Eventually, the validity of the experimental system was confirmed through the function tests.

宇宙科学研究所（ISAS）の宇宙輸送系専門委員会において策定されている宇宙科学・探査分野における宇宙輸送系の中長期ミッションシナリオでは，2040年頃の達成を目指すミッションを「多様な宇宙科学の世界をカバーする軌道間輸送ネットワークを構築する」ことと設定している． ミッション達成に向けて，地上から地球周回軌道へ高頻度に大量の物資や人員を輸送する宇宙往還機を実現するためには，往還飛行において「極超音速飛行」を避けることはできない．本稿では，主に宇宙往還機の実現と競争力向上に資する極超音速エンジンの技術実証を中心に，極超音速飛行に係る技術課題に実証的に取り組むための飛行実験機の目的と検討例について紹介する．

The ammonium dinitramide-based ionic liquid propellant (ADN-based ILP), which is a mixture of ADN, monomethylamine nitrate (MMAN), and urea, is a low toxic monopropellant with a higher performance than that of hydrazine. To clarify the combustion wave structure of ADN-based ILP, which has low volatility, we focused on the relationship between the phase state and temperature in ADN-based ILP combustion and on clarifying the gas-liquid phase reaction. The combustion still image and temperature distribution of ADN-based ILP were obtained by strand burning tests with a high-speed camera. As a result, two stages of the stable temperature region were found in the gas-liquid phase. The pressure dependences of temperature in the stable temperature region were compared with the vapor pressure curves of some chemical substances and with the decomposition temperatures of ADN, MMAN, and urea. Then, it was inferred that the thermal decompositions of ADN, MMAN, and urea, as well as the evaporation of urea had occurred at the first stage of the stable temperature region. Also, it was found that the liquid ammonium nitrate had been dissociated at the second stage of the stable temperature region. For a report on the existence of dissociation products of MMAN and urea vapor on the burning surface at 1.2 MPa, the dissociation of MMAN and evaporation of urea would occur at the first stage of the stable temperature region at 1.2 MPa. As stated above, the combustion wave structure of ADN-based ILP was developed at 1.2 MPa.

This paper describes the development status of a laser ignition system for a solid rocket motor. This system is being developed as a simple, lightweight, and small design with a high resistance to electrical disturbances and a high level of safety. The most notable advantage of this system is that its high level of safety can decrease the cost of launching rockets into space. A laser initiator and a laser safe-and-arm device (laser S/A), which are essential components of the proposed system, were developed. In particular, prototypes of the laser initiator and laser S/A for the ignition of an upper stage rocket motor were manufactured, and some environmental tests, which are required for space rocket devices, were conducted. In addition, the lowest laser energy that is needed to ignite the laser initiator was determined by changing the laser power and operating time of the laser S/A. Furthermore, a small rocket motor vacuum fire test was successfully conducted.

<p>A new space transportation system with an expendable solid-fuel booster and a reusable liquid-fuel orbiter is under consideration as part of activities in JAXA to construct a fully reusable space transportation system in the future. This paper shows this new system's conceptual study results, the system specifications, the new technology to be applied, the requirements to the subsystems, and the prospects.</p>

<p>As a replacement for hydrazine, ammonium-dinitramide-based ionic liquid propellant (ADN-based ILP) has been developed by JAXA and Carlit Holdings Co., Ltd. This propellant is made by mixing three solid powers: ADN, monomethylamine nitrate, and urea. The propellant's theoretical specific impulse is 1.2 times higher than that of hydrazine, and its density is 1.5 times higher at a certain composition. Although ionic liquids were believed to be non-flammable for a long time owing to their low-volatility, recently combustible ILs have been reported. The combustion mechanism of ILs is not yet understood. The objective of this paper is to understand the combustion wave structure of ADN-based ILP. The temperature distribution of the combustion wave in a strand burner test shows a region of constant temperature. This region would indicate boiling in a gas-liquid phase. Thus, the combustion wave structure consists of liquid, gas-liquid, and gas phases. The dependence of boiling point on pressure would identify chemical substances in the gas-liquid phase. The dependence of combustion and ignition characteristics on ADN content is also discussed. </p>

資料番号: PA1510016000

The development of the Epsilon launch vehicle, Japan's next generation solid rocket launcher, has just moved to the final stretch for its first launch scheduled in the summer of 2013 to carry the planetary telescope satellite SPRINT-A. The JAXA appreciates the advantages of combined benefits of the standardized small satellites and the Epsilon's highly efficient launch system in order to increase the level of space activities. The primary purpose of Epsilon is to provide small satellites with a responsive launch that means "Small, Low cost, Fast and Reliable". The attention should be directed toward the innovative design concept of Epsilon, which aims at developing the next generation technologies such as the highly intelligent autonomous checkout system and the mobile launch control. Now that the full-scale development is about to be finished, the most important is what the next step should be beyond the Epsilon. This paper deals with the significance of the Epsilon launch vehicle and how it contributes to the possible evolution of future space transportation systems.

イプシロンロケット二段階開発の最初のステップでは,本質的な低コスト化と即応性の向上を目指す革新的機体システム技術の開発に重きを置いている.推進系の開発においては,H-IIAやM-Vの開発で培われた技術を最大限活用することによって,期間,コスト,リスクを抑え,革新的機体システム技術の早期実証及び近い将来の小型衛星打上げの要求に応える.第1段モータには基幹ロケットのSRB-Aモータを共用し,第2段,第3段にはM-V-5号機の第3段モータ,キックモータをほぼそのまま流用してM-Vをしのぐ輸送効率を達成する.推進系の新しい開発課題は,多様なミッションへの対応能力を高めるPBSの小型液体推進系,そして第1段推力飛行中のロール制御と同コースティング中の3軸制御を担うSMSJ装置である.2013年度の初飛行を目指すイプシロンの推進系開発は,2011年度内に詳細設計を完了して初号機製造に進む見通しである.

The Epsilon rocket, formerly called Advanced Solid Rocket (ASR) launcher, proceeded to the full development phase in August 2010 and its launch site was officially declared to be the Uchinoura Space Center (USC), the home of Japanese solid propellant rocket. The primary purpose of Epsilon is to provide small satellites with a responsive launch that means a low cost, user-friendly and ultimately efficient launch system. The slogan is "Small, Cheap, Fast and Reliable". This outcome is also a result of the excellent endeavors of those who devoted themselves to the next generation solid propellant rocket. However, this is not the final destination. Now that the development was approved, the most important is what the next step should be beyond Epsilon. This paper deals with the significance of the development of Epsilon launch vehicle and how it contributes to the possible evolution of future space transportation systems.

イプシロンロケットの目的は,小型衛星に対して即応性豊かな打ち上げシステム,すなわち自在性と機動性に富みユーザーフレンドリな輸送手段を構築,宇宙への敷居を下げて宇宙科学や宇宙利用の裾野を拡大することにある.一方,これを輸送系の視点でみると,打ち上げシステムの革新というひと言に尽きる.すなわち,今後のロケット開発にあたっては,射場設備と運用はもとより,製造プロセスから搭載系に至るまで,およそロケットの打ち上げに必要な設備や運用をとことんコンパクトで身軽なものにしていこう,それが未来への扉を開く鍵であるという理念である.イプシロンロケットでは,このような壮大なビジョンを実現する第一歩として,ロケットのインテリジェント化やモバイル管制などの超革新技術を開拓,これを世界に先駆けて実証するために,初号機を2013年度に打ち上げる計画である.

A micro solid propellant thruster for simple attitude control of a 10 kg class small spacecraft is currently under development. The prototype has 0.8 mm micro rocket elements, arrayed at a pitch of 1.2 mm on a 22 × 22 mm substance. Initially, solid propellants were used, obtaining only 20% ignition probability with a very long ignition delay (e.g. 1000 ms) as well as very high ignition energy. While observing the tested prototype sample, it became apparent that the main cause of these problems was a gap between the solid propellants and ignition heater. So, the thruster system was improved so that the propellants adhered to the heater. In addition, an ignition charge was used that starts to burn at 210°C, which was acetone having the form of slurry. As a result, a better ignition probability of over 80% in vacuum and half thrust of expectation were gained.

無毒で常温貯蔵可能な液体推進剤として亜酸化窒素(N_2O)/エタノールの組合せに着目し,それによる扱い易い液体推進系の実証研究を進めている.当面の目標として大気吸い込み式極超音速推進系の飛行試験に用いる加速用ロケットエンジンへの適用を目指しているが,その低温環境順応性を活かす衛星・探査機搭載推進系への応用も視野に入れている.これまでに,推力700N級の要素試験供試体を用いた燃焼試験を2シリーズ行って,エンジン噴射器設計のための有用なデータと運用特性を取得してきた.併せて,水冷式燃焼器による燃焼器壁面熱流束分布の測定や厚肉のシリカ繊維強化プラスチックSFRP製燃焼器を用いた燃焼試験によって燃焼器への耐熱複合材料適用の可能性も探っている.

A fully reusable rocket vehicle is proposed to demonstrate good operability characteristics both on the ground and in flight. The proposed vehicle is to be used as a sounding rocket and has the capabilities of ballistic flight, returning to the launch site, and landing vertically making use of clustered liquid hydrogen rocket engines. Before initiating the development of this type of reusable rocket, a small test vehicle with a liquid hydrogen rocket engine was built and flight-tested. A demonstration of vertical landing and exercise of turnaround operation for repeated flights are the major objectives of the test vehicle. Three series of flight tests were performed in 1999, 2001 and 2003, and the flight test operation provided repeated flight environment and many valuable lessons were learned for designing the fully reusable rocket vehicle. © 2005 Published by Lister Science.

The prototype of a solid propellant rocket array thruster for simple attitude control of a 10 kg class micro-spacecraft was completed and tested. The prototype has 10×10 φ0.8 mm solid propellant micro-rockets arrayed at a pitch of 1.2 mm on a 20×22 mm substrate. To realize such a dense array of micro-rockets, each ignition heater is powered from the backside of the thruster through an electrical feedthrough which passes along a propellant cylinder wall. Boron/potassium nitrate propellant (NAB) is used with/without lead rhodanide/potassium chlorate/nitrocellulose ignition aid (RK). Impulse thrust was measured by a pendulum method in air. Ignition required electric power of at least 3–4 W with RK and 4–6 W without RK. Measured impulse thrusts were from 2×10⁻⁵ Ns to 3×10⁻⁴ Ns after the calculation of compensation for air dumping.

Restricting partially and temporally the initial propellant burning surfaces with thin HTPB inhibitors realized a new method of controlling the chamber pressure rise rate at ignition. The merits of the method are to be manufactured easily, to hardly affect the whole motor thrust pattern, and low in cost. The ground firing tests with sub-scale motors have verified the method to be reliable and flexible. The principal concept of a "staged ignition system" is to replace the ignitor main charge by an "ignition cavity" perforated at the fwd.-end of the motor propellant grain. This 'ignition cavity' generates the combustion gas required for igniting the remaining portion of the grain. It has been employed in the designs of two ISAS' solid motors now under development and has contributed to simplification of the ignition systems.

Combustion products flowing in the free port of a solid-rocket motor are responsible for the erosive burning effect. To improve the knowledge of the mechanism governing erosive burning, a nonintrusive X-ray diagnostic system is utilized with the objective of acquiring burning rate data with high temporal and spatial resolutions. The motor has a rectangular cross section, and it is loaded with two solid-propellant slabs parallel to each other. The X-ray source is placed above the motor. The X-ray beam passes through the aluminum windows, which are inserted in the top side of the motor case, and the component transmitted through the slabs is collected by three sensors inserted in the case on the opposite side of the windows. By means of an experimentally determined calibration curve of the attenuation of the X-ray beam through various thicknesses of an unburned propellant, the local time history of the propellant thickness can be deduced and the erosive burning can be evaluated. Results demonstrate a diagnostic reliability and provide data for improving model development and validation of the erosive burning characteristics of the tested solid propellant.

地上静止状態から音速程度までの低速飛翔環境で作動可能なエジェクタ式空気吸い込みロケットにおいては、混合ダクト出口で超音速混合流を形成することが推力増強効果の点でより有利とされている。しかし、未だその作動特性に関する一般性のある理論や経験則は確立されていない。本研究では、低亜音速までの飛翔環境も勘案した上で、超音速混合流を形成するエジェクタ式空気吸い込みロケットの地上静止状態における作動特性を明らかにすることを主目的として、固体ロケットと円筒ダクトを組み合わせて作動特性実験を行うとともに、内部流評価ために新しい解析法を導入して実験結果を詳細に検討している。そして、広い条件にわたる作動性能の予測法を提案し、基本的設計指針を示している。 第1章は序論で、空気吸い込み式ロケットに関する従来の研究動向と問題点を総括し、本研究の目的と意義を述べている。 第2章では、実験装置と方法を説明している。本研究のために試作された小型固体ロケットモータのノズル出口部を円筒型混合ダクト入口に挿入し、混合ダクト出口背圧が、吸い込まれる二次流側総圧(Pts)以下の地上静止状態で実験を行っている。実験供試体としては、ノズルスロート面積(Atp)を一定として開口比の異なる三種類のロケットノズル、および断面積(Ad)の異なる二種類の円筒型混合ダクトを長さを変えて用いている。また一回の実験で広い主流側総圧範囲の計測データを取得するため、ロケットモータ燃焼室圧力(主流側総圧:Ptp)を連続的に降下させている。取得される測定データは、ロケット燃焼室圧力、大気圧、ダクト壁圧およびダクト壁面近傍におけるガス温度である。 第3章では、安定した超音速混合流を形成する条件において、「二次流閉塞モード」と「亜音速混合モード」の二つの作動形態があることを確認している。二次流閉塞モードは従来から知られている作動形態である。一方亜音速混合モードは、二次流が亜音速のまま混合して、ある程度混合が進行した位置で流れが閉塞するもので、従来報告例のない、著者が見い出した作動形態である。本研究では、広い条件にわたって亜音速混合モードとなったことを指摘している。 第4章では、総圧比(Ptp/Pts)、混合ダクト断面積比(Ad/Atp)およびロケットノズル開口比(Aep/Atp)が作動性能に及ぼす影響を系統的に把握するために、内部流の一次元解析法を提案している。この解析法では、混合ダクト出口位置において一様な混合流が形成されていると仮定している。また新たに、主流と二次流が未混合のまま静圧の等しい流れ(Compound-compressible flow以下CCFと略す)を形成すると仮定した、静圧平衡位置が想定されている。CCFの振舞いについては、Compound-flow indicator を導入して判別できることを指摘している。 第5章では、超音速混合流の形成条件に関する解析結果より求めた超音速混合流維持に必要な最小総圧比が、実験値と一致することを示している。また、圧力測定データを用い、対応する混合ダクト出口位置状態と静圧平衡位置状態を推算している。混合ダクト出口位置静圧P2の解析結果は壁圧測定値に良く一致し、また静圧平衡位置の解析結果は、実験で確認された現象をある程度捉えている。特に、静圧平衡位置における二次流側マッハ数M1sの解析結果から、各作動形態に対応する次のような特徴を得ている。すなわち、二次流閉塞モードではPtp/Ptsの値に依らずM1s＝1.1であり、亜音速混合モードではPtp/Pts、Ad/AtpおよびAep/Atpの値に依らずM1s0.52である。二次流閉塞モードについては、本研究の解析法でM1s＝1を仮定することにより,作動性能を予測できることを示している。亜音速混合モードについても、経験的に得られるM1sの値を仮定することにより作動性能予測が可能なこと、またM1sを一定とみなすと、流量率比で代表される作動性能は、Ptp/PtsとAd/Atpの比をCとするとき、ほぼ一義的にCのみに依存することを指摘している。また、Cが一定の条件下では、混合ダクト内部に形成される流れ場は、大まかに混合ダクト直径Dを基準とした寸法で発達すると推察し、実験結果によってこれを実証している。さらに、推力増強効果に関する考察結果に基づいて、より大推力・高比推力を達成する超音速混合流形成型エジェクタ式空気吸い込みロケットの基本的な設計指針を示している。 第6章は結論で、本研究の成果が要約されている。補遺には本文で使用される数式等の詳細が記されている。 以上要するに本論文は、超音速混合流を形成するエジェクタ式空気吸い込みロケットの地上静止状態における作動特性実験ならびに混合ダクト内部流の一次元解析を行い、同型ロケットに関して作動特性の新しい予測法と基本的設計指針を与えるものであり、航空宇宙工学上寄与するところが大きい。よって本論文は博士(工学)の学位請求論文として合格と認められる。

The SAS’ nozzle two-phase flow computer program has recently been revised to achieve a higher .accuracy in calculating thrust characteristic and behavior of particle streamlines. Alumina particles had been gathered in lots of motor firings over a wide range in scale. The particle size distribution characteristics were obtained and the resulted particle sizing equation in terms of the mass averaged particle diameter D43 is quite close to that employed in the improved SPP, i.e., D43 is a unique function of motor throat diameter. Subscale motors containing highly aluminized propellant were fired, whose nozzles were designed to have significant amount of particle impingement and then severe erosion at the exit lip. The nozzle eroded locations were used to verify the computational accuracy of impingement location prediction. It has been shown that the improved two-phase flow program can well predict the particle impingement location by assuming an appropriate particle diameter DpIMP, which is proportional to D43. The proportional coefficient is rather universal.