A six-axis robotic sample changer for high-throughput neutron powder diffraction and texture measurements

Losko, Adrian S.; Vogel, Sven C.; Reiche, Helmut M.; Nakotte, H.

doi:10.1107/s1600576714021797

Cited by 33 publications

(20 citation statements)

References 27 publications

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“…Neutron pulsese merging from ah igh flux/ medium resolution water moderator at 20 Hz are collimated to a1 0mmd iameterb eam spot and enter as ample chambero fc a. 2m 3 .T he sample is held in the sample environment in this chamber, in these experiments, either ar obotic sample changer [ 30] for texture measurements or aJ anis top-loading cryostat for low temperature experiments.D iffracted neutronsa re detectedw ith 1200 3 He de- tector tubes mounted on 53 detector panels, which are arranged on five rings around the incident beam with nominal diffraction angleso f1 448,1 208,9 0 8,6 0 8,a nd 408.F or texture measurements, the data of each detector panel was integrated into 45 histograms (the 16 backscattering panels are integrated into 8h istograms for improved statistics), while for the powder diffraction data collected duringt emperature changes the data was integrated into five histograms, one for each detector ring. The latter improves counting statistics and smears out the effects of weak to moderate preferred orientation due to the vast detector coverage of HIPPO, allowing data analysis that assumes random crystal orientation.…”

Section: Standard Experimentsu Sing Hippomentioning

confidence: 99%

Neutron Diffraction Measurements and Micromechanical Modelling of Temperature‐Dependent Variations in TATB Lattice Parameters

Yeager

Luscher

Vogel

et al. 2016

Propellants Explo Pyrotec

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[c] 1IntroductionTriaminotrinitrobenzene (TATB) is ah igh explosive thati s used in extremely safe ("insensitive") explosive formulations. Twoo ft he most widely used formulationsa re the plastic-bonded explosives( PBX) PBX 9502 (95 wt-% TATB, 5wt-% Kel-F8 00 polymer binder) and LX-17 (92.5 wt-% TATB, 7.5 wt-% Kel-F8 00). The propensity of these PBX formulationst or emain unreactiveu nder aw ide rangeo fp otential insults, including fragment impact and fire disaster scenarios, has led to their widespread applicationa cross many weapons systems [1].W hile TATB is advantageous in this regard, there are three sources of anisotropy in TATB crystals that complicate mechanisms of polycrystalr esponse. First,T ATBh as at riclinic crystal structure that is as ource of crystal anisotropy in its own right [2].S econd, each triclinicu nit cell of TATB possesses two TATB molecules each comprising am odified benzene ring.T he bonds within the modified benzene ring are sufficiently strong that the molecules remain flat and aligned in layersa long the (001)c rystallographic plane. The intermolecularb onds formed within these molecular layers of TATB are strong hydrogen bonds, while the bonds betweena djacent layers are of relatively weaker van der Waals type, leading to stronglya nisotropic deformation and thermal expansion behavior. Third, the geometric morphology of TATB crystals is also anisotropic;d epending on the synthesis route, the graphite-like platelet aspect ratioc an be somewhat mitigated or exaggerated, wheret he large flat surfacesc orrespond to crystallographic (001) planes [3,4].The thermal expansion of single-crystal TATB is entirely reversible. However,b ulk polycrystalline TATB exhibits an irreversible volumee xpansion upon thermal cycling while in Abstract:T riaminotrinitrobenzene (TATB) is ah ighly anisotropic molecular crystal used in several plastic-bonded explosive (PBX) formulations. TATB-based explosives exhibit irreversible volume expansion( "ratchet growth") whent hermally cycled. At heoretical understanding of the relationship betweena nisotropy of the crystal, crystal orientation distribution (texture) of polycrystalline aggregates, and the intergranular interactions leading to this irreversible growth is necessary to accurately develop physics-based predictive models for TATB-basedPBXs under variousthermal environments. In this work, TATB lattice parameters were measured using neutron diffraction duringt hermal cyclingo fl oose powder and ap ressedp ellet. The measured lattice parameters help clarify conflictingr eports in the literature as these new results are more consistent with one set of previous results than another.T he lattice parameters of pressed TATB were also measured as af unction of temperature, showings ome differences from the powder.T his data is used along with anisotropic single-crystal stiffness moduli reported in thel iterature to model the nominal stresses associated with intergranularc onstraints during thermal expansion. The texture of both specimens were characterized...

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Section: Standard Experimentsu Sing Hippomentioning

confidence: 99%

Neutron Diffraction Measurements and Micromechanical Modelling of Temperature‐Dependent Variations in TATB Lattice Parameters

Yeager

Luscher

Vogel

et al. 2016

Propellants Explo Pyrotec

Self Cite

View full text Add to dashboard Cite

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“…This include a system developed by Thyssen Company [11] where a standard X-ray diffractometer with a conventional sample table was equipped with a robot based sample changer to facilitate automated texture analysis of sample series. In a similar vein a robot system is implemented purely as a sample changer in combination with conventional sample tables at the neutron facility ANSTO at the powder diffractometer Echidna [12] and recently at the instrument Hippo at the LANSCE facility [13]. Hessert et al [14] developed a Xray diffraction stress scanner for large samples based on a concept of two cooperating 6-axis robots that position the X-ray tube and the detector in diffraction geometry relative to the component surface -an innovative use of robots which has been recently implemented also in commercial strain diffractometers.…”

Section: Introductionmentioning

confidence: 99%

Improved sample manipulation at the STRESS-SPEC neutron diffractometer using an industrial 6-axis robot for texture and strain analyses

Randau

Brokmeier

Gan

et al. 2015

Nuclear Instruments and Methods in Physics Research Section A:

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“…In 2011 it was decided that a 6 axis robot, capable of texture analysis would be purchased. At that time few if any facilities had this capability, we are currently aware of 2 facilities that can now do this, STRESS-SPEC at FRM II in Munich [4] and at the LANCSE facility in Los Alamos [5]. An Epson C3 6 axis robot was selected.…”

Section: Figure 4 Intensity (A) and Fwhm (B) Of The Measured Peak Vsmentioning

confidence: 99%

Neutron Optics Upgrades to the Residual Stress Diffractometer, KOWARI

Reid

Olsen

Luzin

et al. 2016

Residual Stresses 2016

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Abstract. In the last 5 years a number of significant enhancements have been implemented on the neutron beam strain scanner Kowari at the OPAL reactor in Sydney Australia. These changes have resulted in reduced beam time losses when conducting experiments due to sample and stage alignment, and optics and sample changes. There have been 3 projects, starting in 2011 with a new manual slit system design and collision recovery system, in 2013 with a series of radial collimators and finally with the delivery of a 6 axis robot capable of texture measurements and of running up to 20 samples automatically. IntroductionThe thermal neutron residual strain scanner, Kowari, has been operational since 2007. On the residual strain stress scanning instrument KOWARI the spatial resolution ranges from 0.2 to 1000 mm 3 . The resolution in lattice strain is of the order 0.01% giving a stress resolution in steels of ~ 20 MPa. The instrument has been operated accordingly to ISO/TS 21432-2005 to achieve reproducible and reliable stress measurements [1,2]. Initially sample alignment and changes to the neutron optics were both slow and ergonomically challenging.A project commenced in 2011 to design and manufacture a new neutron optics exchange system, to improve the slit system through improved collision protection and appature control and to allow much faster change over between configurations of the neutron optics (currently, three options are available: slit system, radial collimator, open detector). The new system allows for rectangular gauge volumes of quite a large size range, and has extended toolkit for accurate alignment and built-in anticollision system. After a successfully series of tests with collimators borrowed from the JRR-3M reactor a project commenced in 2013 to design and purchase a series of collimators.Texture measurements have been undertaken for many years using a standard Euler cradle. Sample changes were thus manually made every 4-8 hours depending on sample and conditions. To increase productivity and lower exposures for users a 6 axis robotic sample changer began operating on KOWARI in 2015 which allows automated testing of 20 (in some cases more) samples.

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A six-axis robotic sample changer for high-throughput neutron powder diffraction and texture measurements

Cited by 33 publications

References 27 publications

Neutron Diffraction Measurements and Micromechanical Modelling of Temperature‐Dependent Variations in TATB Lattice Parameters

Neutron Diffraction Measurements and Micromechanical Modelling of Temperature‐Dependent Variations in TATB Lattice Parameters

Improved sample manipulation at the STRESS-SPEC neutron diffractometer using an industrial 6-axis robot for texture and strain analyses

Neutron Optics Upgrades to the Residual Stress Diffractometer, KOWARI

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