Data provided by National Institute of Standards and Technology
These measurements were performed as part of the 2018 Additive Manufacturing Benchmark Test Series (AM-Bench), specifically supporting the melt pool geometry challenge (CHAL-AMB2018-02-MP) and cooling rate challenge (CHAL-AMB2018-02-CR). This dataset and the associated experiments are part of a continuing series of controlled benchmark tests, in conjunction with a conference series, with two initial goals, 1) to allow modelers of Additive Manufacturing processes to test their simulations against rigorous, highly controlled additive manufacturing benchmark test data, and 2) to encourage additive manufacturing practitioners to develop novel mitigation strategies for challenging build scenarios. More information regarding the AMBench 2018 study can be found at www.nist.gov/ambench. Multiple laser scan tracks were performed on bare nickel-based superalloy IN625 substrates using three different combinations of laser power and scan speed. A high-speed infrared camera was used to measure the infrared emissions during each scan track, allowing measurement of the melt pool length and cooling rate of the solidified material. Details related to this dataset are provided in the associated NIST Journal of Research article (in press). The associated publication with experiment details and ex-situ characterization is Lane et. al. 2020 (https://doi.org/10.1007/s40192-020-00169-1).For dataset description article; refer to https://doi.org/10.6028/NIST.AMS.100-53
About this Dataset
Updated: 2024-02-22
Metadata Last Updated:
2018-05-18 00:00:00
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| Title | In Situ Thermography of Single Scan Tracks Performed on Nickel Super Alloy 625 for the 2018 Additive Manufacturing Benchmark Test Series (AM-Bench 2018): Powder Bed Fusion Commercial Build Machine |
|---|---|
| Description | These measurements were performed as part of the 2018 Additive Manufacturing Benchmark Test Series (AM-Bench), specifically supporting the melt pool geometry challenge (CHAL-AMB2018-02-MP) and cooling rate challenge (CHAL-AMB2018-02-CR). This dataset and the associated experiments are part of a continuing series of controlled benchmark tests, in conjunction with a conference series, with two initial goals, 1) to allow modelers of Additive Manufacturing processes to test their simulations against rigorous, highly controlled additive manufacturing benchmark test data, and 2) to encourage additive manufacturing practitioners to develop novel mitigation strategies for challenging build scenarios. More information regarding the AMBench 2018 study can be found at www.nist.gov/ambench. Multiple laser scan tracks were performed on bare nickel-based superalloy IN625 substrates using three different combinations of laser power and scan speed. A high-speed infrared camera was used to measure the infrared emissions during each scan track, allowing measurement of the melt pool length and cooling rate of the solidified material. Details related to this dataset are provided in the associated NIST Journal of Research article (in press). The associated publication with experiment details and ex-situ characterization is Lane et. al. 2020 (https://doi.org/10.1007/s40192-020-00169-1).For dataset description article; refer to https://doi.org/10.6028/NIST.AMS.100-53 |
| Modified | 2018-05-18 00:00:00 |
| Publisher Name | National Institute of Standards and Technology |
| Contact | mailto:[email protected] |
| Keywords | Additive manufacturing , benchmark tests , AMBench , AMBench 2018 , powder bed fusion , nickel super alloy 625 , IN625 , thermography , temperature measurement , melt pool length , cooling rate |
{
"identifier": "6D6EC9B3A4147BE2E05324570681EEC91931",
"accessLevel": "public",
"contactPoint": {
"hasEmail": "mailto:[email protected]",
"fn": "Brandon Lane"
},
"programCode": [
"006:045"
],
"@type": "dcat:Dataset",
"landingPage": "https:\/\/data.nist.gov\/od\/id\/mds2-1931",
"description": "These measurements were performed as part of the 2018 Additive Manufacturing Benchmark Test Series (AM-Bench), specifically supporting the melt pool geometry challenge (CHAL-AMB2018-02-MP) and cooling rate challenge (CHAL-AMB2018-02-CR). This dataset and the associated experiments are part of a continuing series of controlled benchmark tests, in conjunction with a conference series, with two initial goals, 1) to allow modelers of Additive Manufacturing processes to test their simulations against rigorous, highly controlled additive manufacturing benchmark test data, and 2) to encourage additive manufacturing practitioners to develop novel mitigation strategies for challenging build scenarios. More information regarding the AMBench 2018 study can be found at www.nist.gov\/ambench. Multiple laser scan tracks were performed on bare nickel-based superalloy IN625 substrates using three different combinations of laser power and scan speed. A high-speed infrared camera was used to measure the infrared emissions during each scan track, allowing measurement of the melt pool length and cooling rate of the solidified material. Details related to this dataset are provided in the associated NIST Journal of Research article (in press).\u00a0 The associated publication with experiment details and ex-situ characterization is Lane et. al. 2020 (https:\/\/doi.org\/10.1007\/s40192-020-00169-1).For dataset description article; refer to\u00a0 https:\/\/doi.org\/10.6028\/NIST.AMS.100-53",
"language": [
"en"
],
"title": "In Situ Thermography of Single Scan Tracks Performed on Nickel Super Alloy 625 for the 2018 Additive Manufacturing Benchmark Test Series (AM-Bench 2018): Powder Bed Fusion Commercial Build Machine",
"distribution": [
{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/6D6EC9B3A4147BE2E05324570681EEC91931\/CHAL-AMB2018-02-MP_CR_Summary.xlsx.sha256",
"mediaType": "text\/plain"
},
{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/6D6EC9B3A4147BE2E05324570681EEC91931\/CHAL-AMB2018-02-MP_CR_Summary.xlsx",
"format": "A Microsoft Excel spreadsheet",
"description": "This Excel spreadsheet provides a summary and comparison of the melt pool length and cooling rate measurements.",
"mediaType": "application\/vnd.openxmlformats-officedocument.spreadsheetml.sheet",
"title": "Measurement results and summary"
},
{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/6D6EC9B3A4147BE2E05324570681EEC91931\/NIST_DataSetPlot.m",
"format": "MATLAB function",
"description": "This is a MATLAB function that will recreate the radiant temperature profiles and infrared videos that are available in the dataset. The intention of this code is to provide context for the data available in the \"CHAL-AMB2018-02-DataSet.mat\" MATLAB data file. The function is commented.",
"mediaType": "text\/example",
"title": "MATLAB function to recreate the radiant temperature profile plots and infrared video"
},
{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/6D6EC9B3A4147BE2E05324570681EEC91931\/CHAL-AMB2018-02-DataSet.mat",
"format": "MATLAB data file",
"description": "This is a MATLAB data file containing structure arrays for each test. These structures contain the radiant temperature data, relevant test information, and measurements.",
"mediaType": "application\/octet-stream",
"title": "MATLAB data file containing measurements of each test"
},
{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/6D6EC9B3A4147BE2E05324570681EEC91931\/RadiantTemperatureVideos.zip.sha256",
"mediaType": "text\/plain"
},
{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/6D6EC9B3A4147BE2E05324570681EEC91931\/RadiantTemperatureVideos.zip",
"format": "ZIP file containing MPEG-4 thermal videos",
"description": "This compressed folder contains videos of the radiant temperature measurements of each test. These videos are useful in understand the process and the data provided in the dataset. The videos can be recreated from the data using the NIST_DataSetPlot.m MATLAB function which is also provided.",
"mediaType": "application\/zip",
"title": "Videos of the radiant temperature measurements"
},
{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/6D6EC9B3A4147BE2E05324570681EEC91931\/TemperatureProfilePlots.zip.sha256",
"mediaType": "text\/plain"
},
{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/6D6EC9B3A4147BE2E05324570681EEC91931\/TemperatureProfilePlots.zip",
"format": "ZIP file with .jpg and MATLAB .fig plots.",
"description": "A compressed file containing plots containing the temperature profiles from each frame of each test. Plots are provided as both MATLAB figures (.fig) and images (.jpg).",
"mediaType": "application\/zip",
"title": "Plots of the radiant temperature profiles from each test"
},
{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/6D6EC9B3A4147BE2E05324570681EEC91931\/RawCameraData.zip.sha256",
"mediaType": "text\/plain"
},
{
"downloadURL": "https:\/\/data.nist.gov\/od\/ds\/6D6EC9B3A4147BE2E05324570681EEC91931\/RawCameraData.zip",
"format": "ZIP file with .img raw IR camera files",
"description": "This compressed folder contains the raw camera files for each test. The .img files contain the raw camera signals as well as metadata for each frame. A special MATLAB function is required to read these files.",
"mediaType": "application\/zip",
"title": "Raw IR camera files"
},
{
"accessURL": "https:\/\/doi.org\/10.18434\/M31931",
"title": "DOI Access for In Situ Thermography of Single Scan Tracks Performed on Nickel Super Alloy 625 for the 2018 Additive Manufacturing Benchmark Test Series (AM-Bench 2018): Powder Bed Fusion Commercial Build Machine"
}
],
"license": "https:\/\/www.nist.gov\/open\/license",
"bureauCode": [
"006:55"
],
"modified": "2018-05-18 00:00:00",
"publisher": {
"@type": "org:Organization",
"name": "National Institute of Standards and Technology"
},
"theme": [
"Mathematics and Statistics:Modeling and simulation research",
"Materials:Metals",
"Manufacturing:Additive manufacturing"
],
"issued": "2019-09-10",
"keyword": [
"Additive manufacturing",
"benchmark tests",
"AMBench",
"AMBench 2018",
"powder bed fusion",
"nickel super alloy 625",
"IN625",
"thermography",
"temperature measurement",
"melt pool length",
"cooling rate"
]
}
