Bidirectional air turbines for oscillating water column systems: Fast selection applying turbomachinery scaling laws

Thomas H. Carolus, Christoph Moisel
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引用次数: 3

Abstract

The collector of an oscillating water column system (OWC) for wave energy utilization requires a bidirectional turbine that copes with pneumatic power while providing specified impedance or, in terms of an OWC designer, “damping”. Damping is realized by keeping to a specific flow rate through the turbine at a given pressure head due to the individual performance characteristic of the turbine. With the number of turbine designs increasing designers of OWC systems are facing more options to select and dimension a bidirectional turbine. Energy yield, size and hence cost of the turbine and electric generator, operational behaviour, envisaged control strategy and noise emitted by the turbine are possible criteria for selection.

The primary objective of this paper is to describe a simple procedure for making a first choice of a turbine for a particular OWC application. Here we confine ourselves to a family of reaction type of turbines (axial-flow Wells and mixed-flow turbines by Moisel) with their approximately linear pressure head/volume flow rate characteristics. Starting point is the set of non-dimensional steady-state characteristics of each turbine in the family. Utilizing standard scaling laws and a very simple time domain model for the cyclic turbine operation (i.e. based one single sea state and turbine operation assumed to be fixed rotational speed), first estimates of turbine size and rotor speed, number for stages or flows, and performance curves can be determined. The resulting turbine may also serve as a starting configuration for a refined analysis, e.g. the optimization of the turbine and the complete OWC system, utilizing more complex stochastic models. Three case studies illustrate the application of the method: selection and scaling of turbines, effect of collector parameters, turbines in series and parallel.

振荡水柱系统的双向空气涡轮机:应用涡轮机械标度规律的快速选择
用于波浪能利用的振荡水柱系统(OWC)的收集器需要一个双向涡轮机,该涡轮机在提供指定阻抗的同时应对气动动力,或者用OWC设计者的话说,是“阻尼”。阻尼是通过在给定压头下保持通过涡轮的特定流量来实现的,这是由于涡轮的个人性能特性。随着水轮机设计数量的不断增加,OWC系统的设计人员在选择和尺寸上面临着更多的选择。发电量、涡轮机和发电机的大小以及因此产生的成本、运行行为、设想的控制策略和涡轮机发出的噪声都是可能的选择标准。本文的主要目的是描述一个简单的程序,使一个涡轮机的首选为一个特定的OWC应用。这里我们只讨论一类具有近似线性压头/体积流量特性的反应型涡轮机(轴流井和Moisel混合流涡轮机)。起点是家族中每个涡轮机的无量纲稳态特性的集合。利用标准标度定律和循环涡轮运行的非常简单的时域模型(即基于单一海况和涡轮运行假设为固定转速),可以确定涡轮尺寸和转子转速,级数或流量以及性能曲线的第一次估计。由此产生的涡轮机也可以作为精细分析的起始配置,例如,利用更复杂的随机模型对涡轮机和完整的OWC系统进行优化。三个实例说明了该方法的应用:水轮机的选择与标度、集热器参数的影响、水轮机的串联与并联。
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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