Design and Test of Cryogenic Cold Plate for Thermal-Vacuum Testing of Space Components
This paper proposes a novel cryogenic fluid cold plate designed for the testing of cryogenic space components. The cold plate is able to achieve cryogenic temperature operation down to −196 °C with a low liquid nitrogen (LN<sub>2</sub>) consumption. A good tradeoff bet...
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MDPI AG
2019-08-01
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| Series: | Energies |
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| Online Access: | https://www.mdpi.com/1996-1073/12/15/2991 |
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doaj-d9ba58a78cbc4a3b889e40edb38973ed2020-11-25T01:55:47ZengMDPI AGEnergies1996-10732019-08-011215299110.3390/en12152991en12152991Design and Test of Cryogenic Cold Plate for Thermal-Vacuum Testing of Space ComponentsEfrén Díez-Jiménez0Roberto Alcover-Sánchez1Emiliano Pereira2María Jesús Gómez García3Patricia Martínez Vián4Mechanical Engineering Area, University of Alcalá, 28801 Alcalá de Henares, Madrid, SpainMechanical Engineering Area, University of Alcalá, 28801 Alcalá de Henares, Madrid, SpainMechanical Engineering Area, University of Alcalá, 28801 Alcalá de Henares, Madrid, SpainMechanical Engineering Department, Charles III University of Madrid, 28911 Leganés, Madrid, SpainMechanical Engineering Area, University of Alcalá, 28801 Alcalá de Henares, Madrid, SpainThis paper proposes a novel cryogenic fluid cold plate designed for the testing of cryogenic space components. The cold plate is able to achieve cryogenic temperature operation down to −196 °C with a low liquid nitrogen (LN<sub>2</sub>) consumption. A good tradeoff between high rigidity and low thermal conduction is achieved thanks to a hexapod configuration, which is formed by six hinge−axle−hole articulations in which each linking rod bears only axial loads. Thus, there is not any stress concentration, which reduces the diameter of rod sections and reduces the rods’ thermal conduction. This novel design has a unique set of the following properties: Simple construction, low thermal conduction, high thermal inertia, lack of vibrational noise when cooling, isostatic structural behavior, high natural frequency response, adjustable position, vacuum-suitability, reliability, and non-magnetic. Additionally, the presented cold plate design is low-cost and can be easily replicated. Experimental tests showed that a temperature of at least −190 °C can be reached on the top surface of the cold plate with an LN<sub>2</sub> consumption of 10 liters and a minimum vibration frequency of 115 Hz, which is high enough for most vibration tests of space components.https://www.mdpi.com/1996-1073/12/15/2991cold platecryogenicsthermal-vacuum testingvibration test |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Efrén Díez-Jiménez Roberto Alcover-Sánchez Emiliano Pereira María Jesús Gómez García Patricia Martínez Vián |
| spellingShingle |
Efrén Díez-Jiménez Roberto Alcover-Sánchez Emiliano Pereira María Jesús Gómez García Patricia Martínez Vián Design and Test of Cryogenic Cold Plate for Thermal-Vacuum Testing of Space Components Energies cold plate cryogenics thermal-vacuum testing vibration test |
| author_facet |
Efrén Díez-Jiménez Roberto Alcover-Sánchez Emiliano Pereira María Jesús Gómez García Patricia Martínez Vián |
| author_sort |
Efrén Díez-Jiménez |
| title |
Design and Test of Cryogenic Cold Plate for Thermal-Vacuum Testing of Space Components |
| title_short |
Design and Test of Cryogenic Cold Plate for Thermal-Vacuum Testing of Space Components |
| title_full |
Design and Test of Cryogenic Cold Plate for Thermal-Vacuum Testing of Space Components |
| title_fullStr |
Design and Test of Cryogenic Cold Plate for Thermal-Vacuum Testing of Space Components |
| title_full_unstemmed |
Design and Test of Cryogenic Cold Plate for Thermal-Vacuum Testing of Space Components |
| title_sort |
design and test of cryogenic cold plate for thermal-vacuum testing of space components |
| publisher |
MDPI AG |
| series |
Energies |
| issn |
1996-1073 |
| publishDate |
2019-08-01 |
| description |
This paper proposes a novel cryogenic fluid cold plate designed for the testing of cryogenic space components. The cold plate is able to achieve cryogenic temperature operation down to −196 °C with a low liquid nitrogen (LN<sub>2</sub>) consumption. A good tradeoff between high rigidity and low thermal conduction is achieved thanks to a hexapod configuration, which is formed by six hinge−axle−hole articulations in which each linking rod bears only axial loads. Thus, there is not any stress concentration, which reduces the diameter of rod sections and reduces the rods’ thermal conduction. This novel design has a unique set of the following properties: Simple construction, low thermal conduction, high thermal inertia, lack of vibrational noise when cooling, isostatic structural behavior, high natural frequency response, adjustable position, vacuum-suitability, reliability, and non-magnetic. Additionally, the presented cold plate design is low-cost and can be easily replicated. Experimental tests showed that a temperature of at least −190 °C can be reached on the top surface of the cold plate with an LN<sub>2</sub> consumption of 10 liters and a minimum vibration frequency of 115 Hz, which is high enough for most vibration tests of space components. |
| topic |
cold plate cryogenics thermal-vacuum testing vibration test |
| url |
https://www.mdpi.com/1996-1073/12/15/2991 |
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