Wind Turbine Power Curve Exponential Model with Differentiable Cut-in and Cut-out Parts

Romanuke, Vadim

doi:10.20535/1810-0546.2018.2.121504

Cited by 2 publications

(1 citation statement)

References 10 publications

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“…To start the optimization, apart from expected power (2) are set at 0. Special attention must be paid to calculation of expected powers 1 { } K k k , which strongly depend on the wind speed distribution parameters and representation accuracy of wind turbine power curves [12,13]. The expected power is indeed very sensitive to the shape and scale parameters, so their inaccurate determination may badly bias an optimal solution if even the power curves are all represented accurately.…”

Section: Discussionmentioning

confidence: 99%

Iterative Power Maximization by One-Half Cost Dichotomy for Optimizing Wind Farm Deployment

Romanuke

2019

KPI SN

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Background. In deploying a wind farm, it is important to hold a balance of energy generated by wind turbines and costs spent on buying and installing them. However, ranking the energy and costs is commonly uncertain. Besides, the existing methods of optimal wind farm deployment are pretty slow, whereas even optimal numbers of wind turbines of certain types along with their costs and energy produced by them may need to be frequently recalculated. Objective. The goal is to develop a practically rapid method of maximizing the produced energy by minimizing the costs. The method should get rid of ranking the energy and costs. Besides, it should speed up the process of finding optimal numbers of wind turbines. The optimality here is to be interpreted in wide sense implying also fitting wind statistics, controlling the costs and production, and adjusting to energy markets. Methods. Once an expected power for every wind turbine type is calculated, a power maximization problem is formulated in the form of an integer linear programming problem, where optimal numbers of wind turbines of certain types are to be found. This problem involves a span of acceptable annual energy formed by a maximum and a minimum of the annual desired energy. Additionally, costs are constrained. The minimal and maximal numbers of wind turbines of a definite type are constrained also. First, the power maximization problem is solved by an arbitrary large constraining costs. Then the constraining costs are decreased until the solution is nonempty. If the solution is empty, the costs are increased. Every next step of either the decrement or increment is twice smaller than the previous one. This process is continued until the change in the costs becomes sufficiently insignificant. Results. The optimization process is rapidly executed requiring only a few iterations to achieve an optimal solution. In particular, solving optimization problems with five known wind turbine types takes up to one tenth of a second, so a bunch of such problems is solved within a second or so. In general, the optimization requires no less than 3 iterations. After the first iteration, the constraining costs drop too low and the problem has no solution. However, the empty solution at the third iteration is not excluded, and a nonempty solution can appear after a few empty solutions. Nevertheless, an apparent economical impact after applying the wind farm deployment optimization is expectedly strong. There is an example with saving almost 18.4 million euros, which is 28.2 % of the initial (non-optimized) costs. Such gains, however, are expectedly decreasing as the relative difference between a maximum and a minimum of the annual desired energy is shortened. Conclusions. The presented approach is a method of successive optimization. It allows to avoid solving the twocriterion problem for simultaneous energy maximization and cost minimization for deploying wind farms. The computational core of this method is that the expected power output is maximized via solving an integer linear ...

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Section: Discussionmentioning

confidence: 99%

Iterative Power Maximization by One-Half Cost Dichotomy for Optimizing Wind Farm Deployment

Romanuke

2019

KPI SN

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The Method of the Estimating Wind Power Plant’s Installed Capacity Utilization Factor

Podhurenko¹,

Гетманець²,

Terekhov³

2021

Èlektron. model.

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Знайдено аналітичну залежність коефіцієнта використання встановленої потужності вітрової електричної установки (ВЕУ) від параметрів її характеристики потужності і параметрів вітрового кадастру на передбачуваній місцевості розміщення вітрової електричної станції при заданій висоті розташування осі її вітроколеса. На основі дослідження характеристик потужності 50 вітрових електричних установок різних виробників потужністю від 2,0 до 3,6 МВт показано, що ці характеристики добре описуються двопараметричним інтегральним розподілом Вейбула — Гніденка (ІРВГ). Отримано простий асимптотичний вираз для коефіцієнта використання встановленої потужності в залежності від двох параметрів диференціального розподілу Вейбула — Гніденка для швидкості вітру і двох параметрів ІРВГ для характеристики потужності ВЕУ. Показники, отримані за допомогою даного асимптотичного виразу, відрізняються від результатів кількісних розрахунків коефіцієнта використання встановленої потужності не більше, ніж на 2 %, і тому можуть бути використані для вибору або проектування певної ВЕУ на передбачуваній місцевості на заданій висоті розташування осі вітроколеса.

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Wind Turbine Power Curve Exponential Model with Differentiable Cut-in and Cut-out Parts

Cited by 2 publications

References 10 publications

Iterative Power Maximization by One-Half Cost Dichotomy for Optimizing Wind Farm Deployment

Iterative Power Maximization by One-Half Cost Dichotomy for Optimizing Wind Farm Deployment

The Method of the Estimating Wind Power Plant’s Installed Capacity Utilization Factor

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