Design, Qualification and Integration Testing of the High-Temperature Resistance Temperature Device for Stirling Power System

Chan, Tak Shing; Elisii, Remo; Hill, Dennis; White, J. D.; Lewandowski, Edward J.; Oriti, Salvatore M.

doi:10.2514/6.2015-3903

Cited by 2 publications

(3 citation statements)

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“…The acceptance of accuracy is correlated with accuracy level. The RTD correlation can predict the accepted temperature with acceptable accuracy [31]. In many applications, the necessity of accuracy comes with the focus on each of repeatability and stability of the sensor, therefore, the features of stability and repeatability are often confused with the accuracy level, but the important thing is to understand the difference between them in order to choose type of metal to application purpose in designated location.…”

Section: Rdts Accuracymentioning

confidence: 99%

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A Comparative Study about Accuracy Levels of Resistance Temperature Detectors RTDs Composed of Platinum, Copper, and Nickel

Kako

2023

NJES

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Platinum, copper, and nickel were founded the best metals used in resistance temperature detectors RTDs. They commonly used in laboratory and industrial applications because they provide accurate and reliable measurements in a wide temperature range from (- 200 to 850 °C). They have high conductivity, sensitivity, and hardness to resist strain shock, pressure, and vibration. The accuracy level of them depends on reliability, stability, repeatability, linearity, and response to time. This study aims to determine and compare the accuracy of these three metals in regarding to their features which include stability, repeatability, and response time. The study has gathered and analyzed the data of these suitable and precise metals and compared with each other. The results showed that platinum is widely needed for RTDs due to its precision, stability, higher accuracy, and linearity output, while copper and nickel are not stable or repeatable as platinum. It was indicated that temperature coefficient of resistance TCR for nickel is bigger and for copper is medium, but for platinum is lower.

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Section: Rdts Accuracymentioning

confidence: 99%

“…The analysis from [16][17][18][19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34] in above section (5. Methods and materials) will summarized as in table 2.…”

Section: Basic Characteristicsmentioning

confidence: 99%

A Comparative Study about Accuracy Levels of Resistance Temperature Detectors RTDs Composed of Platinum, Copper, and Nickel

Kako

2023

NJES

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“…By using the thermal bridge, the RTD is not exposed to the full hot-end temperature, but it is able to project hot-end temperature for monitoring purposes. 5 Convertor dimensional inspection uncovered some small dimensional changes that point to the possibility that the RTD thermal bridge could be influencing heater head geometry. However, a detailed review of the data showed that the dimensional biases towards the RTD thermal bridge seen with ASC-E3 #2 preceded the installation of the RTD thermal bridge, and the changes simply grew over time.…”

Section: A Heat Collector Crowningmentioning

confidence: 99%

Advanced Stirling Radioisotope Generator EU2 Anomaly Investigation

Lewandowski¹,

Oriti²

2016

14th International Energy Conversion Engineering Conference

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The Advanced Stirling Radioisotope Generator (ASRG) Engineering Unit 2 (EU2) is the highest fidelity electrically-heated Stirling radioisotope generator built to date. NASA Glenn Research Center (GRC) completed the assembly of the ASRG EU2 in September, 2014 using hardware from the now cancelled ASRG flight development project. The ASRG EU2 integrated the first pair of Sunpower's ASC-E3 Stirling convertors (ASC-E3 #1 and #2) in an aluminum generator housing with Lockheed Martin's Engineering Development Unit (EDU) 4 controller. After just 179 hours of EU2 generator operation, the first power fluctuation occurred on ASC-E3 #1. The first power fluctuation occurred 175 hours later on ASC-E3 #2. Over time, the power fluctuations became more frequent on both convertors and larger in magnitude. Eventually the EU2 was shut down in January, 2015. An anomaly investigation was chartered to determine root cause of the power fluctuations and other anomalous observations. A team with members from GRC, Sunpower, and Lockheed Martin conducted a thorough investigation of the EU2 anomalies. Findings from the EU2 disassembly identified proximate causes of the anomalous observations. Discussion of the team's assessment of the primary possible failure theories, root cause, and conclusions is provided. Recommendations are made for future Stirling generator development to address the findings from the anomaly investigation. Additional findings from the investigation are also discussed.convertors and larger in magnitude, up to 9.4 W. Early power fluctuations were less than 2 seconds in duration, while later drops in power lasted for hours. Eventually the EU2 was shut down in January, 2015.Given the flight-like fidelity of the EU2 hardware, with the ASC-E3 convertors and the EDU 4 controller, and the flight-like rigor that had been used to assemble the generator housing assembly (GHA), such an early failure was both unexpected and disconcerting. The EU2 was intended to be part of a broader program to establish a reliability database for future Stirling-based power systems, 3 but this failure was a setback to that initiative. An anomaly investigation was chartered to determine root cause of the power fluctuations, to the extent possible, so as to learn from this event and then apply insights gained to future dynamic power conversion systems. The EU2 anomaly investigation team included members from GRC, Sunpower, and LM. Various GRC technology experts were brought in as needed to support different phases of the investigation.This paper chronicles the EU2 anomaly investigation process that took place in 2015. Findings from the disassembly and inspection of the GHA and ASC-E3 convertors are discussed, along with the proximate cause of the power fluctuations. Extensive analysis, modeling, and follow-on testing was conducted, leading to possible failure theories and an assessment of likely root cause and conclusions. Recommendations are provided for future Stirling generator development. A. The ASRG EU2This section provides the reader with a ...

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Design, Qualification and Integration Testing of the High-Temperature Resistance Temperature Device for Stirling Power System

Cited by 2 publications

References 4 publications

A Comparative Study about Accuracy Levels of Resistance Temperature Detectors RTDs Composed of Platinum, Copper, and Nickel

A Comparative Study about Accuracy Levels of Resistance Temperature Detectors RTDs Composed of Platinum, Copper, and Nickel

Advanced Stirling Radioisotope Generator EU2 Anomaly Investigation

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