Gas network topology optimization for upcoming market requirements

2011 8th International Conference on the European Energy Market (EEM) Pub Date : 2011-05-25 DOI:10.1109/EEM.2011.5953035

Armin Fugenschuh, Benjamin Hiller, Jesco Humpola, T. Koch, Thomas Lehmann, R. Schwarz, J. Schweiger, J. Szabó

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引用次数: 17

Abstract

Gas distribution networks are complex structures that consist of passive pipes, and active, controllable elements such as valves and compressors. Controlling such network means to find a suitable setting for all active components such that a nominated amount of gas can be transmitted from entries to exits through the network, without violating physical or operational constraints. The control of a large-scale gas network is a challenging task from a practical point of view. In most companies the actual controlling process is supported by means of computer software that is able to simulate the flow of the gas. However, the active settings have to be set manually within such simulation software. The solution quality thus depends on the experience of a human planner. When the gas network is insufficient for the transport then topology extensions come into play. Here a set of new pipes or active elements is determined such that the extended network admits a feasible control again. The question again is how to select these extensions and where to place them such that the total extension costs are minimal. Industrial practice is again to use the same simulation software, determine extensions by experience, add them to the virtual network, and then try to find a feasible control of the active elements. The validity of this approach now depends even more on the human planner. Another weakness of this manual simulation-based approach is that it cannot establish infeasibility of a certain gas nomination, unless all settings of the active elements are tried. Moreover, it is impossible to find a cost-optimal network extension in this way. In order to overcome these shortcomings of the manual planning approach we present a new approach, rigorously based on mathematical optimization. Hereto we describe a model for finding feasible controls and then extend this model such that topology extensions can additionally and simultaneously be covered. Numerical results for real-world instances are presented and discussed.

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面向未来市场需求的燃气网络拓扑优化

配气网络是由被动管道和主动可控元件(如阀门和压缩机)组成的复杂结构。控制这样的网络意味着为所有活动组件找到一个合适的设置，这样就可以在不违反物理或操作限制的情况下，将指定数量的天然气通过网络从入口输送到出口。从实际应用的角度来看，大规模燃气网络的控制是一项具有挑战性的任务。在大多数公司中，实际控制过程是由能够模拟气体流动的计算机软件来支持的。但是，活动设置必须在此类仿真软件中手动设置。因此，解决方案的质量取决于人类规划人员的经验。当气体网络无法满足传输需求时，拓扑扩展就开始发挥作用。这里确定了一组新的管道或活动元件，使扩展的网络再次接受可行的控制。问题是如何选择这些扩展，以及将它们放置在何处，以使总扩展成本最小。工业实践是再次使用相同的仿真软件，根据经验确定扩展，将其添加到虚拟网络中，然后尝试找到可行的有源元件控制。这种方法的有效性现在更多地取决于人类的规划者。这种基于手动模拟的方法的另一个缺点是，除非尝试了所有有效元素的设置，否则它无法确定特定气体指定的不可行性。而且，用这种方法是不可能找到成本最优的网络扩展的。为了克服人工规划方法的这些缺点，我们提出了一种严格基于数学优化的新方法。在此，我们描述了一个寻找可行控制的模型，然后扩展该模型，使拓扑扩展可以额外地同时覆盖。给出并讨论了实际实例的数值结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2011 8th International Conference on the European Energy Market (EEM)

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