GasLib—A Library of Gas Network Instances

Schmidt, Martin; Aßmann, Denis; Burlacu, Robert; Humpola, Jesco; Joormann, Imke; Kanelakis, Nikolaos; Koch, Thorsten; Oucherif, Djamal; Pfetsch, Marc E.; Schewe, Lars; Schwarz, R.; Sirvent, Mathias

doi:10.3390/data2040040

Cited by 96 publications

(69 citation statements)

References 16 publications

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“…Furthermore, we impose a JCC on the interval I CC = [0, 4]. We consider a discretization of dt = 60[s] and dx ≈ 1[km], again slightly adapted to the individual length of the edges, applied to the same subgrid of the GasLib-40 network [40] as above. Note that this coarse discretization is possible due to the chosen numerical scheme, the IBOX scheme (2).…”

Section: Gas-to-power System: Comparison Of Single and Joint Chance Cmentioning

confidence: 99%

Optimal Inflow Control Penalizing Undersupply in Transport Systems with Uncertain Demands

Göttlich¹,

Korn²,

Lux³

2019

Progress in Industrial Mathematics at ECMI 2018

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In this paper, we address the task of setting up an optimal production plan taking into account an uncertain demand. The energy system is represented by a system of hyperbolic partial differential equations (PDEs) and the uncertain demand stream is captured by an Ornstein-Uhlenbeck process. We determine the optimal inflow depending on the producer's risk preferences. The resulting output is intended to optimally match the stochastic demand for the given risk criteria. We use uncertainty quantification for an adaptation to different levels of risk aversion. More precisely, we use two types of chance constraints to formulate the requirement of demand satisfaction at a prescribed probability level. In a numerical analysis, we analyze the chance-constrained optimization problem for the Telegrapher's equation and a real-world coupled gas-to-power network.

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Section: Gas-to-power System: Comparison Of Single and Joint Chance Cmentioning

confidence: 99%

Optimal Inflow Control Penalizing Undersupply in Transport Systems with Uncertain Demands

Göttlich¹,

Korn²,

Lux³

2019

Progress in Industrial Mathematics at ECMI 2018

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“…Numerical setting Table 2 provides summary statistics for all networks. We test the traditional Belgian network from a previous study (De Wolf & Smeers, 2000), the German networks from the open data set GasLib (Schmidt et al, 2017), and Chinese networks of various sizes provided by CNPC. For each network, we implement all four methods: IPLA-De, IPLA-Ba, IPLA-New, and 3SCR.…”

Section: 1mentioning

confidence: 99%

Optimizing natural gas pipeline transmission with nonuniform elevation: A new initialization approach

Xue

Deng

Shen

2019

Naval Research Logistics

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In this paper, we develop an iterative piecewise linear approximation approach with a novel initialization method to solve natural gas pipeline transmission problems with the nonuniform network elevation. Previous approaches, such as energy minimization methods, cannot be applied to solve problems with the nonuniform network elevation because they exclude pressure range constraints, and thus provide solutions far from optimum. We propose a new initialization model that considers pressure range constraints and improves the optimality of the solutions and the computational efficiency. Furthermore, we extend the energy minimization methods and provide the necessary conditions under which the extended methods operate in networks with the nonuniform elevation. We test the performances of the methods with previously reported pipeline networks from the literature, with the open data set GasLib, and with our industrial collaborator. The initialization approach is shown to be more efficient than the method with fixed initial breakpoints. The newly proposed initialization approach generates solutions with a higher accuracy than the extended energy minimization methods, especially in large‐size networks. The proposed method has been applied to natural gas transmission planning by the China National Petroleum Corporation and has brought a direct profit increase of 330 million U.S. dollars in 2015‐2017.

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“…Finally, we discuss the results of our network reduction techniques applied to three small‐scale to medium‐scale academic, but realistic gas networks and two large‐scale real‐world gas networks. The academic networks are freely available online (see Schmidt et al ) and the real‐world instances are the low‐calorific and high‐calorific gas networks of the German gas transport company Open Grid Europe GmbH…”

Section: Network Reduction Techniquesmentioning

confidence: 99%

“…On average, these nonconvex MINLPs have 2187 variables and 3733 constraints. We used the standard models provided by the GasLib , which all are feasibility problems. BARON is able to solve 2 out of the 10 unreduced instances.…”

Section: Network Reduction Techniquesmentioning

confidence: 99%

“…Finally, we discuss the results of our network reduction techniques applied to three small-scale to medium-scale academic, but realistic gas networks and two large-scale real-world gas networks. The academic networks are freely available online (see Schmidt et al [40]) and the real-world instances are the low-calorific and high-calorific gas networks of the German gas transport company Open Grid Europe GmbH. 1 In contrast to the water and power network instances considered so far, the gas networks that we consider here contain active elements like valves (switches) to block gas flow, control valves to reduce gas pressure, and compressor stations that are used to increase gas pressure.…”

Section: Gas Networkmentioning

confidence: 99%

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Algorithmic results for potential‐based flows: Easy and hard cases

et al. 2018

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Potential‐based flows are an extension of classical network flows in which the flow on an arc is determined by the difference of the potentials of its incident nodes. Such flows are unique and arise, for example, in energy networks. Two important algorithmic problems are to determine whether there exists a feasible flow and to maximize the flow between two designated nodes. We show that these problems can be solved for the single source and sink case by reducing the network to a single arc. However, if we additionally consider switches that allow to force the flow to 0 and decouple the potentials, these problems are NP‐hard. Nevertheless, for particular series‐parallel networks, one can use algorithms for the subset sum problem. Moreover, applying network presolving based on generalized series‐parallel structures allows to significantly reduce the size of realistic energy networks.

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GasLib—A Library of Gas Network Instances

Cited by 96 publications

References 16 publications

Optimal Inflow Control Penalizing Undersupply in Transport Systems with Uncertain Demands

Optimal Inflow Control Penalizing Undersupply in Transport Systems with Uncertain Demands

Optimizing natural gas pipeline transmission with nonuniform elevation: A new initialization approach

Algorithmic results for potential‐based flows: Easy and hard cases

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