Long life of 20–30 years.
Low depreciation due to the lack of mechanical and thermal machinery.
Ability to generate on‐site consumption and save on energy transmission and distribution costs.
Low installation time (less than two years).
Low maintenance costs and ease of operation.
No production costs including the costs of fuel, marketing, and wages.
Usable in remote areas.
Generation of clean energy with no pollution.
Insignificant use of water.
Providing employment opportunities.
Independency on fossil fuels.
The most important disadvantages of the grid‐connected PV plants are:
Occupying a large land area.
No energy production at night without energy storage system.
High investment cost in addition to investment barriers.
Reduced output power at high temperatures and at the end of operation period.
Requiring a land suitable for construction and having access to the power network.
Different electricity purchase policies in different countries.
Taking time to obtain construction permits.
Some of the crises in the global energy demand and environment are:
Annual increase in energy demand.
Limited fossil fuel resources.
Increased environmental pollution from fossil fuels.
Increased CO2 emission in the atmosphere, causing global warming.
Frequent and severe storms, drought, and sea level rises.
Given the PV plants advantages and disadvantages and global energy crises, it turns out that a large numbers of PV plants are needed to achieve long‐term climate goals and to address the energy crises. Therefore, a significant growth of PV plants across the planet is expected in the near future.
The International Energy Agency (IEA) has forecast the global installed solar plants capacity by 2030 as shown in Figure 1.15. This prediction is based on considering various scenarios as described below [10].
There are uncertainties during the Covid‐19 pandemic, its economic and social impacts, and the policy responses. The stated policies assume that the Covid‐19 is gradually brought under control in 2021, and the global economy returns to pre‐pandemic levels in the same year.
The delayed recovery scenario is designed with the same policy assumptions as in the stated policies scenario, but a prolonged pandemic causes lasting damage to economic prospects. The global economy returns to its precrisis size only in 2023, and the pandemic ushers in a decade with the lowest rate of energy demand growth since the 1930s.
The sustainable development scenario assumes the energy system on track to achieve sustainable energy objectives in full, including the Paris Agreement, energy access, and air quality goals.
The new net‐zero emissions by 2050 case (NZE2050) extend the sustainable development scenario analysis. A rising number of countries and companies are targeting net‐zero emissions by midcentury. These are achieved in the sustainable development scenario, putting global emissions on track for net‐zero by 2050. The NZE2050 includes the first detailed IEA modeling of what would be needed in the next 10 years to put global CO2 emissions on track for net zero by 2050 [10].Figure 1.15 Global solar PV and coal‐fired installed capacity by scenario, 2010–2030.Source: IEA [10].
Based on the IEA forecasts about the PV plant installation capacity, it can be concluded that:
For the stated policies scenario, the PV plant installation capacity grows to about 250%.
For the sustainable development scenario, the PV plant installation capacity increases to about 420%.
For the NZE2050 scenario, the PV plant installation capacity grows to about 530%.
As a result, for the worst‐case scenario, a PV plant installation capacity of 1250 GW is expected to be added to the existing capacity by 2030.
1.5 A Review on the Design of Large‐Scale PV Power Plant
For the construction of a LS‐PVPP, it is necessary to conduct preliminary studies, feasibility studies, and to obtain initial permits. Then, the most important stage is the design and engineering of PV plant. In this section, an overview of the technical literature is presented.
The relationships between solar geometry and the theory of PV cells are presented in [11]. A guide on the fundamental problems of a PV power plant is given in [12]. In [13], a method to locate a LS‐PVPP is presented. Reference [14] focuses on the control and performance of large‐scale PV plants and examines the requirements of the grid code, active and reactive power control, and the dynamics of large‐scale PV plants under various temperature and radiation conditions.
A PV handbook that deals with the details and theories of PV modules and solar inverters are given in [15]. A design and installation guide for equipment of a PV plant is proposed in [16]. A solution for reducing subscribers' bills by installing a PV plant is discussed in [17]. In [18], feasibility studies for the PV plants are presented. A method for the optimization of the design of a PV plant to maximize its energy production through the shading analysis is proposed in [19]. Reference [20] presents a method for selecting the optimal inverter and PV modules for a PV power plant. A method for determining the cable size of a PV plant is presented in [21]. In [22], few topologies for the monitoring system of a PV plant are examined. The design of distribution transformers for a PV plant based on harmonic specifications is discussed in [23]. The protection system of a PV plant is discussed in [24, 25], and the grounding system design is presented in [26].
1.6 Outline of the Book
In Chapter 2, a review of the design requirements of a LS‐PVPP is presented and various equipment of the plant is introduced. In Chapter 3, first the key points and general definitions of feasibility studies of a PV plant are introduced. Then, the criteria and requirements of a feasibility study report for a large‐scale PV plant are presented.
In Chapter 4, the network connection studies of a PV power plant are discussed and the main parts of the network connection studies and its requirements
