Kaldellis Stand-Alone and Hybrid Wind Energy Systems

1 Overview of stand-alone and hybrid wind energy systems
J.K. Kaldellis,     TEI of Piraeus, Greece Abstract:
This chapter introduces the reader to the definition and development of stand-alone and hybrid energy systems. Emphasis is given to the description of wind-based stand-alone hybrid energy systems as well as to the use of energy storage for the support of such configurations. Accordingly, the most established applications of similar systems are presented, including some representative real-life examples. Future prospects of such systems are discussed. Key words: stand-alone system hybrid system wind power energy storage remote consumer 1.1 Introduction
At the beginning of the twenty-first century, almost every inhabitant of the industrialized world has access to a constant electricity supply and thus electricity may be viewed as a significant aspect of contemporary societies, similar to fresh water and clean air. Nevertheless, this is not the case for the planet’s entire population. According to official statistics (European Commission, 1999), almost two billion people worldwide have no direct access to electrical networks with 500 000 of them living in the European Union and other financially developed countries. Afar from decision centres and having limited political influence, isolated consumers are usually abandoned, facing a dramatically insufficient infrastructure (Jensen, 2000; Kaldellis et al., 2001a). In this context, autonomous stand-alone wind-power systems have proven to be one of the most interesting and environmentally friendly technological solutions for the electrification of remote consumers, especially in the presence of high wind potential (Kaldellis, 2002, 2004). Small wind turbines are able to produce an annual total of only few MW h which, although limited in absolute numbers, makes a considerable difference in upgrading living standards in the remote areas of our planet. The required investment cost, however, may be quite high, especially in cases of medium quality wind potential regions and no-load rejection operational conditions, i.e. the entire load demand must be met. One of the most expensive components of a stand-alone system is the energy storage device, necessary to guarantee the required system reliability. Thus, in cases of increased system autonomy the energy storage contribution to the initial or the total operational cost is found to be dominant (Kaldellis, 2003, 2008a). In addition, energy storage systems are usually land-intensive, need a lot of maintenance and often need to be replaced every specific time period, thus increasing the operational cost of the system. To avoid oversizing of energy storage configurations, wind-based stand-alone systems are augmented with another available energy source, such as solar energy, hydropower or biomass. Such a stand-alone hybrid energy system is an option worth considering (Muselli et al., 1999; Kaldellis and Kavadias, 2001; Kaldellis et al., 2006a). Recapitulating, stand-alone wind energy systems are electricity-generating systems, based on the operation of one or more wind turbines, being also remote (not connected) from the central electrical grids. In this context, import or export of electricity is not permitted, but there are occasions where a stand-alone system can be connected to an existing electrical network, e.g. emergency status (Bueno and Carta, 2006). Accordingly, hybrid energy systems incorporate two or more electricity generation options, based either on the exploitation of renewable energy sources (RES) or on small thermal power units, e.g. diesel-electric generators or even micro-turbines. Note, however, that with regards to the case currently studied, the first electricity generation option is by definition wind energy. 1.2 Description of a wind-based stand-alone energy system
A typical wind energy stand-alone system (see Fig. 1.1) includes: 1.1 Typical wind energy stand-alone system. • one or more (usually small) wind converters of No kW; • an appropriate energy storage device, e.g. a lead–acid battery storage array, able to guarantee ho hours of autonomy, or equivalently with energy storage capacity Qmax and maximum permitted discharge capacity Qmin; • an AC/DC rectifier of Nr kW in case the energy storage installation operates on DC current; • a charge controller of Nc kW; • a UPS (uninterruptible power supply) of Np kW in order to guarantee high quality AC electricity generation; • a DC/AC inverter of NpkW. 1.2.1 Wind turbine
The rated power of the selected wind-turbine(s) depends on the system electricity demand, the available wind potential and the operational characteristics of the machine (Vlachou et al., 1999). Keep also in mind that the wind-turbine output curves are given at standard-day conditions, without air humidity. Thus, in real-day conditions, the output of the turbine depends (Kaldellis et al., 2004) on the wind speed value V at hub height, the manufacturer’s power curve NW = NW* (V) at standard day conditions and the air density ? at the installation area, thus: 1.1 Finally, note that the air density value depends on the ambient temperature and pressure as well as on the corresponding air humidity (Houghton and Brock, 1980). 1.2.2 Energy storage
There are several different energy storage alternatives, such as flywheels, hydraulic storage, pumped hydro, battery storage and even fuel cells (Kaldellis and Zafirakis, 2007; Kaldellis et al., 2009a), with lead-acid batteries being one of the most widely applied solutions adopted in similar size applications. The operational principle of an energy storage installation in this kind of systems is based on the accumulation of available energy surplus in order for it to be used during periods of inadequate wind. More precisely, the energy storage size is given in units of the time-period that the storage can cover the average load without the contribution of other power sources. Hence, the energy storage system used is defined by the installation’s hours of energy autonomy ho, the corresponding operational characteristics, e.g. the output voltage Ub for battery storage systems, the maximum permitted depth of discharge DODL and the overall efficiency of the energy storage branch. Note that the latter includes the energy storage process (e.g. rectifier and charge controller losses), the standing losses owing to the energy storage self-discharge, the losses of the line connecting the storage branch apparatus and finally any electricity generation losses (e.g. inverter). 1.2.3 System electronic devices
To ensure smooth operation for the remote consumer under investigation an AC/DC rectifier of nominal power Nr related to the wind turbine rated power No is necessary to convert the incoming three-phase AC voltage UAC from the wind turbine excess power to a nominal UDC corresponding to the DC current accepted by the system charge controller. Note that in cases of pumped hydro (Kaldellis et al., 2001b) or small compressed air energy storage (CAES) (Zafirakis and Kaldellis, 2009) systems this transformation is not required. The output of the AC/DC rectifier enters a DC/DC charge controller of Nc rated power that charges the system batteries with a charging voltage Ucc, slightly higher than the respective of the batteries Ub and feeds any existing DC loads of the installation. The corresponding charge rate Rch depends on the charge voltage and the battery charge current, while the discharge rate is defined by the battery voltage and the corresponding discharge current. Finally, any excess energy is forwarded to other low-priority loads or is directly rejected into a water-heating dump load by the controller, if no other low-priority loads exist. The energy storage electricity production branch is based on either an appropriate DC/AC inverter converting the DC output of the batteries into standard 50 Hz current of operational voltage 220/380 V or a small hydro turbine (in the case of pumped hydro). Several other electricity options are described in the next chapters of this book. The maximum power Np of the inverter (hydro turbine) should be capable of meeting the AC consumption peak load demand, including a future increase margin (e.g. 30%), while its efficiency strongly varies with the load demand. In fact, during partial load operation remarkable efficiency decrease is encountered. In Fig. 1.2 one may find a typical inverter efficiency curve for its entire operational range. 1.2...