Experiment based development of a non-isothermal pore network model with secondary capillary invasion
Micro-Macro Transactions Vol 33
Autoren
Parameter
Mehr zum Buch
In this thesis, PN simulations of drying are compared with experimentally obtained data from drying of a representative 2D microfluidic network in SiO2 under varying thermal conditions with the aim to identify governing physical pore scale effects. Gravity and viscous effects are disregarded in this thesis. Instead drying with slight local temperature variation and drying with imposed thermal gradients are studied. Based on this investigation, a powerful non‐isothermal PNM is developed. This model incorporates i) the phenomena associated with the temperature dependency of pore scale invasion, namely thermally affected capillary invasion and vapor flow as well as ii) the secondary effects induced by wetting liquid films of different morphology.
Buchkauf
Experiment based development of a non-isothermal pore network model with secondary capillary invasion, Nicole Vorhauer
- Sprache
- Erscheinungsdatum
- 2019
Lieferung
Zahlungsmethoden
Feedback senden
- Titel
- Experiment based development of a non-isothermal pore network model with secondary capillary invasion
- Untertitel
- Micro-Macro Transactions Vol 33
- Sprache
- Englisch
- Autor*innen
- Nicole Vorhauer
- Verlag
- Docupoint Verlag
- Verlag
- 2019
- ISBN10
- 3869121564
- ISBN13
- 9783869121567
- Kategorie
- Skripten & Universitätslehrbücher
- Beschreibung
- In this thesis, PN simulations of drying are compared with experimentally obtained data from drying of a representative 2D microfluidic network in SiO2 under varying thermal conditions with the aim to identify governing physical pore scale effects. Gravity and viscous effects are disregarded in this thesis. Instead drying with slight local temperature variation and drying with imposed thermal gradients are studied. Based on this investigation, a powerful non‐isothermal PNM is developed. This model incorporates i) the phenomena associated with the temperature dependency of pore scale invasion, namely thermally affected capillary invasion and vapor flow as well as ii) the secondary effects induced by wetting liquid films of different morphology.