Computational optimization of a 3D printed collimator

Fahima Islam; Jiao Lin; Thomas Huegle; Ian Lumsden; David Anderson; Amy Elliott; Bianca Haberl; Garrett Granroth

doi:10.3233/JNR-190139

Computational optimization of a 3D printed collimator

Fahima Islam, Jiao Lin, Thomas Huegle, Ian Lumsden, David Anderson, Amy Elliott, Bianca Haberl, Garrett Granroth

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

This contribution describes the computational methodology behind an optimization procedure for a scattered beam collimator. The workflow includes producing a file that can be manufactured via additive methods. A conical collimator, optimized for neutron diffraction experiments in a high pressure clamp cell, is presented as an example. In such a case the scattering from the sample is much smaller than that of the pressure cell. Monte Carlo Ray tracing in MCViNE was used to model scattering from a Si powder sample and the cell. A collimator was inserted into the simulation and the number and size of channels were optimized to maximize the rejection of the parasitic signal coming from the complex sample environment. Constraints, provided by the additive manufacturing process as well as a specific neutron diffractometer, were also included in the optimization. The source code and the tutorials are available in c3dp (Islam (2019)).

Original language	English
Pages (from-to)	155-168
Number of pages	14
Journal	Journal of Neutron Research
Volume	22
Issue number	2-3
DOIs	https://doi.org/10.3233/JNR-190139
State	Published - 2020

Funding

We gratefully acknowledge J.J. Molaison for his help during the experimental evaluation on SNAP. A portion of this research used resources at the SNAP beamline of the Spallation Neutron Source, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. The optimization constraints were determined through the expert technical efforts of D. Goldsby and D. Siddel. This work is supported by Oak Ridge National Laboratory (ORNL), Laboratory Directed Research and Development funds under contract DE-AC05-00OR8828. This research used the ORNL CADES compute resources.

Keywords

3D printing
High pressure
Monte Carlo simulation
optimization

Access to Document

10.3233/JNR-190139

Cite this

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abstract = "This contribution describes the computational methodology behind an optimization procedure for a scattered beam collimator. The workflow includes producing a file that can be manufactured via additive methods. A conical collimator, optimized for neutron diffraction experiments in a high pressure clamp cell, is presented as an example. In such a case the scattering from the sample is much smaller than that of the pressure cell. Monte Carlo Ray tracing in MCViNE was used to model scattering from a Si powder sample and the cell. A collimator was inserted into the simulation and the number and size of channels were optimized to maximize the rejection of the parasitic signal coming from the complex sample environment. Constraints, provided by the additive manufacturing process as well as a specific neutron diffractometer, were also included in the optimization. The source code and the tutorials are available in c3dp (Islam (2019)).",

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AU - Islam, Fahima

AU - Lin, Jiao

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AU - Lumsden, Ian

AU - Anderson, David

AU - Elliott, Amy

AU - Haberl, Bianca

AU - Granroth, Garrett

PY - 2020

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AB - This contribution describes the computational methodology behind an optimization procedure for a scattered beam collimator. The workflow includes producing a file that can be manufactured via additive methods. A conical collimator, optimized for neutron diffraction experiments in a high pressure clamp cell, is presented as an example. In such a case the scattering from the sample is much smaller than that of the pressure cell. Monte Carlo Ray tracing in MCViNE was used to model scattering from a Si powder sample and the cell. A collimator was inserted into the simulation and the number and size of channels were optimized to maximize the rejection of the parasitic signal coming from the complex sample environment. Constraints, provided by the additive manufacturing process as well as a specific neutron diffractometer, were also included in the optimization. The source code and the tutorials are available in c3dp (Islam (2019)).

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Computational optimization of a 3D printed collimator

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Computational optimization of a 3D printed collimator

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