The fundamental understanding of droplet dynamics is the critical prerequisite to the prediction of natural processes and the optimization of technical systems. Many of these processes happen under extreme ambient conditions - e.g. high pressure or extreme temperatures - and can already be found in technical applications, despite the absence of fundamental knowledge. This is exactly where the new Collaborative Research Center focuses on. The goal is to gain a profound physical understanding of the essential processes. This understanding is the basis for new ways of analytical and numerical descriptions. Thereby, an improved prediction of large systems in nature or in technical applications shall be possible.
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211 to 220 of 241 Results
Subarea B2(Universität Stuttgart)
Apr 12, 2021
Experimental investigation of droplet evaporation under extreme conditions by temporally highly resolved laser diagnostic methods
Subarea B1(Universität Stuttgart)
Apr 12, 2021
Investigation of the behavior of supercooled droplets concerning evaporation, condensation and freezing at different boundary conditions
Atomization.cine
Apr 12, 2021 - Drop collision with a hot, dry solid substrate
Unknown - 494.2 MB - MD5: 19d0d9c84486cc4d58b14f0b77c4a7ab
Oberflächentemperatur: 290°C; Aufprallgeschwindigkeit: 1.71 m/s; Tropfendurchmesser: 2.2 mm;
Dancing.cine
Apr 12, 2021 - Drop collision with a hot, dry solid substrate
Unknown - 951.2 MB - MD5: bbef2ab35e3d7fc41dd24593e43e773e
Oberflächentemperatur: 170°C; Aufprallgeschwindigkeit: 0.71 m/s; Tropfendurchmesser: 2.2 mm;
Deposition.cine
Apr 12, 2021 - Drop collision with a hot, dry solid substrate
Unknown - 2.5 GB - MD5: 016c9450726c2a3345e9c8c2f6e11ce4
Oberflächentemperatur: 130°C; Aufprallgeschwindigkeit: 1.19 m/s; Tropfendurchmesser: 2.2 mm;
Rebound.cine
Apr 12, 2021 - Drop collision with a hot, dry solid substrate
Unknown - 1.1 GB - MD5: e85e91a943348db840ae3e53edd768f6
Oberflächentemperatur: 330°C; Aufprallgeschwindigkeit: 0.71 m/s; Tropfendurchmesser: 2.2 mm;
dataset1_01_freezingSessileDrop.avi
Apr 12, 2021 - Experimental investigations of the freezing process of supercooled water droplets close to a solid wall
AVI Video - 5.5 MB - MD5: 849afa076dd1d8d3c35b3cb9a8373f0d
Supercooled solidification of a sessile drop (T = -15.8 °C)
dataset1_02_freezingWithinHele-ShawCell.avi
Apr 12, 2021 - Experimental investigations of the freezing process of supercooled water droplets close to a solid wall
AVI Video - 13.7 MB - MD5: 13c78eef5e2652e83449ac783ebae11c
Supercooled solidification of a drop in the Hele-Shaw cell (T = -15.8 °C)
dataset1_03_iceLayerPropagation.avi
Apr 12, 2021 - Experimental investigations of the freezing process of supercooled water droplets close to a solid wall
AVI Video - 5.5 MB - MD5: 41b76f0953441815dcf34e2236495a55
Dendritic solidification of a drop in the Hele-Shaw cell (T = -10.7 °C)
dataset2_01_planar.avi
Apr 12, 2021 - Experimental investigations of the freezing process of supercooled water droplets close to a solid wall
AVI Video - 9.8 MB - MD5: a4b4b5663488885f23c984adf5382654
Small supercooling results in only planar growth of the initial ice layer (T = -2.44 °C)
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