Machine Learning for Improved Gas Network Models in Coordinated Energy
Systems
- URL: http://arxiv.org/abs/2209.12731v1
- Date: Mon, 26 Sep 2022 14:34:26 GMT
- Title: Machine Learning for Improved Gas Network Models in Coordinated Energy
Systems
- Authors: Adriano Arrigo, Mih\'aly Dol\'anyi, Kenneth Bruninx, Jean-Fran\c{c}ois
Toubeau
- Abstract summary: We propose a neural-network optimization method to improve non-constrained natural gas flow dynamics.
Our proposed framework is capable of considering bidirectionality without having recourse to complex potentially inaccurate neuralification approaches.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The current energy transition promotes the convergence of operation between
the power and natural gas systems. In that direction, it becomes paramount to
improve the modeling of non-convex natural gas flow dynamics within the
coordinated power and gas dispatch. In this work, we propose a
neural-network-constrained optimization method which includes a regression
model of the Weymouth equation, based on supervised machine learning. The
Weymouth equation links gas flow to inlet and outlet pressures for each
pipeline via a quadratic equality, which is captured by a neural network. The
latter is encoded via a tractable mixed-integer linear program into the set of
constraints. In addition, our proposed framework is capable of considering
bidirectionality without having recourse to complex and potentially inaccurate
convexification approaches. We further enhance our model by introducing a
reformulation of the activation function, which improves the computational
efficiency. An extensive numerical study based on the real-life Belgian power
and gas systems shows that the proposed methodology yields promising results in
terms of accuracy and tractability.
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