Globally optimal scheduling of an electrochemical process via data-driven dynamic modeling and wavelet-based adaptive grid refinement

IF 2 3区工程技术 Q2 ENGINEERING, MULTIDISCIPLINARY Optimization and Engineering Pub Date : 2023-11-24 DOI:10.1007/s11081-023-09860-6

Chrysanthi Papadimitriou, Tim Varelmann, Christian Schröder, Andreas Jupke, Alexander Mitsos

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Abstract

Electrochemical recovery of succinic acid is an electricity intensive process with storable feeds and products, making its flexible operation promising for fluctuating electricity prices. We perform experiments of an electrolysis cell and use these to identify a data-driven model. We apply global dynamic optimization using discrete-time Hammerstein–Wiener models to solve the nonconvex offline scheduling problem to global optimality. We detect the method’s high computational cost and propose an adaptive grid refinement algorithm for global optimization (AGRAGO), which uses a wavelet transform of the control time series and a refinement criterion based on Lagrangian multipliers. AGRAGO is used for the automatic optimal allocation of the control variables in the grid to provide a globally optimal schedule within a given time frame. We demonstrate the applicability of AGRAGO while maintaining the high computational expenses of the solution method and detect superior results to uniform grid sampling indicating economic savings of 14.1%.

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基于数据驱动动态建模和小波自适应网格优化的电化学过程全局最优调度

琥珀酸的电化学回收是一个耗电量大的过程，原料和产品具有可储存性，操作灵活，有望应对电价波动。我们执行电解电池的实验，并使用这些来确定一个数据驱动的模型。本文采用离散时间Hammerstein-Wiener模型进行全局动态优化，求解非凸离线调度问题的全局最优性。针对该方法计算量大的缺点，提出了一种基于拉格朗日乘子的自适应网格优化算法(agago)，该算法采用控制时间序列的小波变换和基于拉格朗日乘子的优化准则。agago用于网格中控制变量的自动优化分配，以在给定的时间框架内提供全局最优调度。我们证明了agago的适用性，同时保持了求解方法的高计算费用，并检测到优于均匀网格采样的结果，表明经济节省14.1%。

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来源期刊

Optimization and Engineering 工程技术-工程：综合

CiteScore

4.80

自引率

14.30%

发文量

审稿时长

>12 weeks

期刊介绍： Optimization and Engineering is a multidisciplinary journal; its primary goal is to promote the application of optimization methods in the general area of engineering sciences. We expect submissions to OPTE not only to make a significant optimization contribution but also to impact a specific engineering application. Topics of Interest: -Optimization: All methods and algorithms of mathematical optimization, including blackbox and derivative-free optimization, continuous optimization, discrete optimization, global optimization, linear and conic optimization, multiobjective optimization, PDE-constrained optimization & control, and stochastic optimization. Numerical and implementation issues, optimization software, benchmarking, and case studies. -Engineering Sciences: Aerospace engineering, biomedical engineering, chemical & process engineering, civil, environmental, & architectural engineering, electrical engineering, financial engineering, geosciences, healthcare engineering, industrial & systems engineering, mechanical engineering & MDO, and robotics.