A unified approach to simulate thermal hydraulic instabilities and the mutual interactions using transient distributed model

In the present work, a 1-D thermal-hydraulic model is developed to simulate two phase flow boiling for a working coolant R134a circulating inside a single horizontal channel which includes a surge tank. The TH model is the first of its kind which solves the transient conservation equations based on...

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Bibliographic Details
Published in:International journal of multiphase flow 2023-11, Vol.168, p.104567, Article 104567
Main Authors: Garg, Vishal, Shivam, Shuvendu, Verma, Arun, Dutta, Goutam
Format: Article
Language:English
Subjects:
Density wave oscillations
Distributed model
In-house model
Interaction of instabilities
Ledinegg excursion
Pressure drop oscillations
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Summary:In the present work, a 1-D thermal-hydraulic model is developed to simulate two phase flow boiling for a working coolant R134a circulating inside a single horizontal channel which includes a surge tank. The TH model is the first of its kind which solves the transient conservation equations based on distributive formulations without the incorporation of quasi-steady state approximation and still can simulate pure pressure drop oscillations (PDOs), Ledinegg excursion and density wave oscillations (DWOs), and the co-existence of those instabilities as well using a unified approach by employing appropriate external characteristic curves. The model is validated with the available experimental data and then, further used for intended purpose as mentioned above. Finally, the notable conclusions are drawn based on the simulations conducted. Results indicate that the initial equilibrium position in the negative slope region of the pressure drop vs. mass flux curve is unstable, leading to Ledinegg excursion or PDOs based on the steepness of the external pump characteristic curve. Increased surge tank volume extends PDOs. For Ledinegg excursion, the unstable position shifts to positive slope regions, and gets stabilized or destabilized depending on the occurrence of DWOs. DWOs are more likely at low mass flux and positive slope region. With a constant mass flow rate from an external pump, DWOs occur with a surge tank upstream of the heated section but not without it. Simulations demonstrate coexistence of PDOs, Ledinegg excursion, and DWOs in certain situations. [Display omitted] •Developed a 1D thermal-hydraulic (TH) model to simulate instabilities with surge tank•First of its kind model using distributive formulations to solve transient equation•Model validated with available data, and simulates the relevant TH instabilities.•Demonstrate occurrence of such instabilities and their mutual coexistence
ISSN:0301-9322
DOI:10.1016/j.ijmultiphaseflow.2023.104567