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口頭

Neutron diffraction bulk texture measurement using compact neutron source

徐 平光; 角田 龍之介*; 高村 正人*; 大竹 淑恵*; 鈴木 裕士

no journal, , 

Neutron diffraction is a powerful probe to acquire the bulk averaged information for better bridging the microscopic crystal lattice with the macroscopic properties, in contrast with the X-ray and electron diffractions which are capable for investigating the surface/very limited local regions of polycrystalline materials. In Japan, the RIKEN compact accelerator-driven neutron source facility (RANS) has been developing to improve the instrumental accessibility of neutron diffraction experimental studies, which were mostly carried out on large-scale neutron source facilities. Here, our latest technical progress in RANS neutron diffraction bulk texture measurement will be reported. The comparable study between RANS and another large-scale neutron diffraction facility suggests that the high stereographic resolution realized through the proper fine division of neutron detector panel is valuable to improve the precision and reliability of texture measurement, together with the careful scattering intensity correction of neutron patterns.

口頭

Energy resolution evaluation of decoupled neutron moderator for stress measurements via neutron diffraction with compact neutron source

角田 龍之介*; 高村 正人*; 徐 平光; 岩本 ちひろ*; 高梨 宇宙*; 大竹 淑恵*; 栗原 諒*; 高橋 進*; 鈴木 裕士

no journal, , 

During the production of high-strength steel structural parts, the residual stress is necessary to be well controlled for the better dimensional accuracy and the longer service life. The neutron diffraction measurement is a good candidate to monitor the microscopic lattice strain of polycrystalline materials in bulk average. RANS (Riken Accelerator-driven Compact Neutron Source) has been developed and upgraded aiming at in-house, on-site and on-demand measurements to meet with industrial needs. Recently, the phase volume fractions and the bulk textures of steel materials have been measured successfully at RANS. In order to measure the lattice strain at RANS, it is required to improve the energy resolution to observe slight peak shift, and the decoupled moderator is thought as a good solution method for that. In this study, a new decoupled moderator consisting of polyethylene with 20 cmm thickness and B$$_{4}$$C rubber was designed and fabricated, and its neutron beam characteristic was investigated in order to improve the time energy resolution to realize in-house neutron stress measurement at RANS. Here, the preliminary results of the resolutions comparing between the new decoupled moderator and the traditional coupled moderators with 20 and 40 mm thickness polyethylene will be reported together with the scattering angle dependent instrumental resolution of the linear neutron position-sensitive detector.

口頭

鉄鋼材料の集合組織測定研究に関する大型中性子施設とRIKEN小型中性子源の連携

徐 平光; 高村 正人*; 池田 義雅*; 角田 龍之介*; 高橋 進*; 箱山 智之*; 岩本 ちひろ*; 大竹 淑恵*; 鈴木 裕士

no journal, , 

自動車の軽量化のために使用されている高張力薄鋼板は、プレス成形による加工性が低いことから、生産不良が多い。そのため、プレス成形性を向上させる手段の一つとして、鋼材の集合組織制御に期待が寄せられている。実用に供される金属材料の微視組織は不均一な集合組織を有している。圧延板の加工性など金属材料のマクロな特性を議論する際には、金属材料のバルク平均の集合組織を考慮することが適切だと考えられる。中性子線を用いた集合組織測定は、高い透過性と大きなゲージ体積という特徴を生かして、加工性に直結する金属材料のバルク平均情報を容易に測定することができる。しかしながら、日本国内に限らず、世界中には、集合組織が測定できる中性子回折装置が極めて少ない。そこで、我々は研究用原子炉施設(JRR-3)の定常中性子源と大強度陽子加速器施設(J-PARC)のパルス中性子源を用いた集合組織測定技術を確立し、世界トップレベルの測定精度を有する集合組織測定装置を開発した。近年、中性子評価技術をより広く普及するため、理化学研究所が"いつでも、どこでも、手軽に利用できる"をキャッチフレーズとした小型中性子源(RANS)の開発を進めており、我々がこれまでに培ってきたノウハウを最大限に生かして、RANSを用いた粉末回折技術や集合組織測定技術の開発に挑戦してきた。本発表では、JRR-3, J-PARCおよびRANSで開発した鉄鋼材料の集合組織測定技術を簡単に紹介するとともに、中性子回折による集合組織測定研究に関して大型中性子施設と小型中性子源との連携案について議論する。

口頭

Neutron diffraction with RANS for industrial "on-site" applications

高村 正人*; 岩本 ちひろ*; 徐 平光; 角田 龍之介*; 栗原 諒*; 箱山 智之*; 池田 義雅*; 鈴木 裕士; 大竹 淑恵*

no journal, , 

High strength steels are becoming more and more important in automotive body structures for good weight reduction, providing further requirement in the balance between strength and formability. Numerical models in forming simulations taking into account the texture evolution may accurately analyze macroscopic plastic behavior, through referring to local surface texture measurement using Electron backscatter diffraction or X-ray diffraction. In contrast, neutron diffraction may measure the microstructure factors including bulk-averaged texture, enable to more deeply understand the mechanisms of deformation behavior. Such neutron diffraction studies usually require large-scale experimental facilities like a reactor and a large accelerator, so meet certain difficulty in the instrumental accessibility. To solve these problems, Riken Accelerator-driven Compact Neutron Source (RANS) has been developed. On-site evaluation of microstructural factors enables us to analyze metal deformation processes more efficiently. Authors have recently succeeded in accurately measuring the texture evolution of an IF steel and also in determining the retained austenite volume fraction of multi-phase steels, by optimizing the beam condition and layout of collimators, samples, detectors, etc. These results show the possibility of practical use of an in-house compact neutron source in laboratories of universities, research institutes and industrial firms.

口頭

In-house texture measurement using RIKEN accelerator-driven compact neutron source

徐 平光; 高村 正人*; 池田 義雅*; 角田 龍之介*; 岩本 ちひろ*; 箱山 智之*; 大竹 淑恵*; 鈴木 裕士

no journal, , 

Neutron diffraction is known as a powerful probe to determine the bulk averaged microstructural factors of metals and alloys. Compact neutron sources are being paid much attention for providing wide instrumental accessibility towards many potential on-site neutron diffraction applications, because of less technical complexity compared with large-scale neutron facilities. Here, the RIKEN Accelerator-Driven Compact Neutron Source (RANS) has been developed to establish the in-house technical environment of engineering diffraction for texture measurements. The measured texture of an interstitial-free (IF) steel sheet at RANS was found well consistent with the corresponding result obtained from a large-scale high-resolution time-of-flight neutron diffractometer. Such comparison suggests that RANS may be used to evaluate the ex situ texture characteristics of steel materials. Moreover, the increment of the output power and the addition of the neutron detector will be carried out in near future to enable rapid microstructural factor measurement of other high value-added metallic materials.

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