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International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 2020 75

International Journal of Energy Economics and 
Policy

ISSN: 2146-4553

available at http: www.econjournals.com

International Journal of Energy Economics and Policy, 2020, 10(6), 75-79.

Wind Power: Current State and Perspectives

Vladimir Yu. Linnik1*, E. Yu. Voronova2, Larisa V. Pavlyuk3, Alexey Zich4

1State University of Management, Moscow, Ryazansky pr., 99, Russian Federation, 2Shakhty Automobile and Road Construction 
Institute (Branch) of Platov SRSPU (NPI), Lenin Square, 1, Shakhty, Rostov region, Russian Federation, 3State University of 
Management, Russian Federation, Moscow, Ryazansky pr., 99, Russia, 4Energy Efficiency Consultant, MS QF GmbH, Oderwitz, 
Germany. *Email: vy_linnik@guu.ru

Received: 17 May 2020 Accepted: 27 August 2020 DOI: https://doi.org/10.32479/ijeep.9938

ABSTRACT

Due to the depletion of resources for traditional energy, as well as due to the gradual abandonment of nuclear power in a number of countries, the 
world pays great attention to energy conservation and energy efficiency, one of the main sources of which is renewable energy, which includes wind 
energy. Wind power is the most developed renewable energy industry (excluding hydro), which affects its economic characteristics. Thus, onshore wind 
power plants are characterized by one of the lowest indicators of the cost of electricity production among alternative types of generation. However, 
offshore wind power plants are still inferior to some types of renewable energy sources and are twice the level of traditional thermal power plants. 
In this article, the authors consider the state and prospects of development of the world wind energy. The distribution of installed capacity of wind 
power plants by regions of the world is analyzed and the shares of countries in the total installed capacity are determined. The leading countries were 
identified as well as the reasons for the rapid growth of wind generation in these countries along with the measures of state support. The state and 
prospects of wind power development in Russia are considered, and it is also noted that the Russian Federation has significant potential in the field 
of wind power development, which makes it possible to make optimistic forecasts regarding the provision of electricity to remote areas of Russia. 
The technical electric power potential of wind energy is about 17.1 TW/year, which is an order of magnitude higher than the amount of electricity 
generated by all power plants in the country in 2018. The scientific increment is to identify the key problems facing the domestic wind power industry.

Keywords: Energy Efficiency, Energy Saving, Wind Energy, Wind Power Plants, Russian Wind Energy Market 
JEL Сlassifications: Q42, Q47, P28

1. INTRODUCTION

The development of industrial production and improving the 
welfare of the population requires an increase in the need to 
use traditional sources of energy, the reserves of which are not 
unlimited in nature. The constant growth of energy consumption 
in the world, from 20.75 trillion kW in 2015 to a projected level of 
33.4 trillion kW in 2030, has led to increased level of attention to 
energy efficiency and energy conservation issues around the world.

Until recently, the cost of installing a 1 kW wind generator 
averaged about $ 1000, and according to experts’ forecasts, it 

will decrease to $ 420 by 2020 (Lyons et al., 2018). As of the 
end of 2018, electricity generated from wind power has begun to 
demonstrate competitiveness with energy obtained from traditional 
sources. Given the finite reserves of traditional energy sources, 
their prices will increase, which means that the cost of energy 
produced from oil, gas and coal will also increase, which further 
increases the competitiveness of wind energy.

Thus, the use of relatively cheap and cleaner energy is a significant 
factor in improving energy efficiency and energy conservation, 
which contributes to the economic growth of society, reducing 
its needs for traditional energy and improving the environment.

This Journal is licensed under a Creative Commons Attribution 4.0 International License



Linnik, et al.: Wind Power: Current State and Perspectives

International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 202076

2. LITERATURE REVIEW

Figure 1 shows data on the distribution of total installed capacity of 
wind power plants (wind turbines) by regions of the world, which 
shows that the greatest development of wind power has been in 
Europe, North America and Asia. Approximately one-third of the 
world’s wind power is generated on the Asian continent (Okazaki 
et al., 2015).

According to the results of 2018, the top three world leaders in 
total wind power capacity (WPC) included China (184.6 GW), the 
United States (96.5 GW) and Germany (56.2 GW) (Sidorovich, 
2019; Zhang, 2019). The share of the top eight countries in the 
world wind energy balance is about 83%, with more than a third of 
the world’s installed capacity owned by China and twice as much 
as the United States (Figure 2) (Zhang, 2019; Pakhomov, 2019).

Taking into account the geographical location of the European 
Union countries, the greatest opportunities for using wind energy 
are available in Denmark, France, Germany, Norway, Great 
Britain, Spain, the Netherlands, Italy and France. In this regard, 
the European Union is implementing a project to create a system 
of high-voltage transmission lines that will unite all wind farms 
in Europe in a single network.

Worldwide interest in wind power has increased so much that 
industrial and military concerns have become interested in the 
production of such installations.

Let’s briefly consider the state of wind power in the main countries 
implementing renewable energy development programs (REN).

3. RESULTS

3.1. China
In China, the development of renewable energy, especially wind 
energy, is considered as one of the priority areas of economic 
development. The country is implementing a major state program 
to stimulate the economy, with a total investment of $ 586 billion. 
Of this amount, 25% is allocated for the implementation of projects 
on environmental protection, development of renewable energy 
and energy efficiency. The spread of wind power in China is 
happening at a rapid pace, largely due to the state support (Lema 
and Ruby, 2007).

In 2018, China’s installed wind power capacity reached 184.6 GW, 
which is 9.7% of the country’s total installed power capacity and 
about 35% of the world’s wind capacity. In 2018, China’s wind 
farms generated 366 billion kW, which accounted for 5.2% of the 
country’s total electricity generation (Tyaglin, 2017).

China ranks first in the world in terms of installed wind farms. The 
capacity of the largest wind farm in China is about 10 GW with 
the possibility of increasing to 40 GW at a project cost of $17.6 
billion. For comparison, the capacity of one of the world’s largest 
Sayano-Shushenskaya HPS is 6.7 GW (Lema and Ruby, 2007).

To a large extent, this was made possible by the development of 
China’s own production of equipment for wind turbines. Currently, 
there are about seventy manufacturers of equipment for the wind 
energy industry in China.

3.2. South Korea
Currently, the share of REN in the country’s electricity generation 
is 8%. According to previously published documents, the Korean 
authorities planned to increase the share of renewable energy 
sources to 20% by 2030, with solar and wind energy leading the 
way.

The new draft energy plan stipulates that the share of REN should 
reach 30-35% by 2040. The draft policy includes a gradual shift 
away from coal and nuclear power, the two main pillars of South 
Korea’s current energy supply. At the same time, the role of natural 
gas will grow. Today, 44% of electricity is generated from coal.

South Korea has a developed shipbuilding and heavy industry, 
which is a good foundation for creating an offshore wind energy 
industry.

Doosan Heavy Industries said last year that it would lead a project 
supported by the South Korean government to develop an 8 MW 
offshore wind turbine that would both operate in the domestic 
market and compete globally. Offshore wind power will play an 

Figure 1: Wind power plant capacity by region

Source: Based on the authors’ research

Figure 2: The share of countries in the total installed (WPC)

Source: Based on the authors’ research



Linnik, et al.: Wind Power: Current State and Perspectives

International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 2020 77

important role in South Korea’s energy future. Consultants from 
Wood Mackenzie predict 6.4 GW of offshore wind farms in the 
country by 2030.

3.3. Turkey
The first wind farm zone was built in Izmir in 1998. In 2006, the 
total capacity of wind turbines was about 19 MW, and in 2007, 
the capacity increased to almost 140 MW. According to reports 
prepared by the Turkish Wind Energy Association (TÜREB), in 
2018, investments in the wind energy sector amounted to 650 
million dollars, which led to an increase in the total installed 
capacity of wind power plants in 2018 to 7.3 GW, and the wind 
energy sector itself grew by 7.24%, producing an additional 
497.25 MW.

As of the end of 2019, the capacity of 198 wind turbines in Turkey 
was 8 MW, which is 1.2% of wind generation worldwide (650 
GW).

By 2023, Turkey plans to invest € 15 billion in the construction 
of wind farms. The country’s renewable energy development 
plan calls for bringing the installed capacity of Turkish wind 
power to 23 GW by 2023. According to TÜREB, during this time, 
wind farms with a total capacity of 451 MW will be built in the 
economically significant province of Izmir, which accounts for $ 
10.2 billion of Turkish export and $ 7.5 billion of Turkish import. 
As a result, in Izmir, where the first wind farm in Turkey was built, 
the capacity of wind farms will increase from 1549 to 2000 MW, 
and this region will account for 65% of all electricity generated 
by Turkish wind farms.

3.4. The USA
According to the American wind energy Association, the installed 
capacity of wind power in 2018 reached 96.5 GW. There are 56,800 
wind turbines operating in 41 states.

The growth of the US wind power industry in recent years has 
been made possible by the demand for this energy resource from 
companies in various industries that are not directly related to 
the energy sector. So in 2018, direct contracts (PPA) were signed 
for the supply of wind energy to companies with a total volume 
of 4,203 GW. AWEA estimates that the portfolio of wind energy 
projects under construction or in the final stages of development 
has reached 35.1 GW (Sugimoto, 2019). The US energy 
information administration (EIA) has estimated that by the end 
of 2019, US wind power will provide 6.9% of industrial-scale 
electricity generation.

The cost of energy produced by wind farms is still relatively high 
in the United States, but with the increase in the size of wind farms 
and the development of technologies, we can expect a decrease 
in the cost of energy to 2-3 cents/kW, especially in areas with a 
relatively high average annual wind speed (Ratner, 2012; Anup 
et al., 2019).

The rapid development of wind power in the United States in 
recent years has been made possible by government support for 
the development of the industry. For example, when building a 

new wind farm, the state allocates a so-called tax credit to the 
company (Simão et al., 2017; Gillenwater et al., 2014).

3.5. Germany
Currently, in Germany, wind energy is one of the most important 
renewable energy sources and ranks third in the world in total 
installed wind power capacity after China and the United States. 
At the beginning of 2018, the total installed capacity of Germany’s 
wind power plants was 56.2 GW, of which the capacity of mainland 
wind farms reached 50.777 GW. In 2016, the share of wind 
power in total electricity consumption in Germany was 13.2%, 
significantly ahead of bio-and hydro-power (Ibrahim, 2017; Sow 
et al., 2019).

In line with industry trends, the average size of wind turbines is 
also increasing. The largest share of wind power is accounted for 
by installations with a capacity of 2 MW, but in projects introduced 
in Germany in 2017, the average capacity of a wind generator has 
already reached almost 3 MW.

Active development of wind power in Germany began after the 
Chernobyl disaster. It was then that the government program 
for the development of wind energy was launched, and after the 
adoption of the law “Stromeinspeisegesetz vom 7.12.1990,” the 
development of the industry accelerated even more. According 
to this law, energy sales companies are required to buy electricity 
from solar and wind power producers with a capacity of up to 
5 MW at a higher price than before the law was adopted. The 
difference in price should be covered by energy sales companies at 
the expense of ultimate consumers. The law adopted in Germany 
has become a model for supporting RES in many countries 
around the world. 19 European countries, as well as Japan, Brazil 
and China, have used this model in their legislation. Following 
the adoption of the law “Stromeinspeisegesetz vom 7.12.1990” 
in 2000, Germany adopted the law on renewable energy (Das 
Erneuerbare-Energien-Gesetz [EEG]). Thanks to these legislative 
acts, by 2002 the total capacity of the German wind power industry 
reached 10.0 GW (Ketterer, 2014; Usmanova, 2019).

Offshore wind energy is actively developing in Germany. By 2030 
The German government intends to increase the total capacity of 
the offshore national wind energy complex to 25 GW. For this 
purpose, it is planned to build at least 33 offshore wind farms.

In Germany, there are several large companies that produce wind 
turbines (Vestas, Enercon, Repower, Nordex, Fuhrlander), which 
share in the local market is about 65%.

3.6. India
The development of wind power in India began in 1952, when a 
project was initiated to study the possibilities of using wind energy 
in the country. Large-scale development of wind power in India 
began in 1986, when the first demonstration wind installations 
were built in the coastal areas of Maharashtra, Gujarat and Tamil 
Nadu, equipped with 55 and 110 kW Vestas wind turbines.

According to 2018 data, India became the fourth country in the 
world in terms of installed wind power capacity with an indicator 



Linnik, et al.: Wind Power: Current State and Perspectives

International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 202078

of 34,293 GW. In 2017, wind power in India accounted for almost 
10% of the total installed power generation capacity, generating 
52.67 GW of electricity, which is almost 3% of the total electricity 
production in the country (Dipen et al., 2020; Shawon et al., 2013).

The rapid development of wind power in India was the result of 
a number of legislative acts adopted by the Government of the 
country. Thanks to the decisions taken, wind energy costs in India 
have rapidly started to decrease (Dipen et al., 2020; Shawon et al., 
2013). The wind energy tariff reached a record low of 3.4 us cents 
per kilowatt hour in 2017 without any direct or indirect subsidies 
(Dipen et al., 2020).

The Ministry of New and Renewable Energy has also developed 
a national offshore wind energy policy that aims to promote the 
deployment of offshore wind turbines up to 12 nautical miles 
offshore. The first 100 MW demonstration project is expected to 
be launched in Gujarat. Given that India has a 7600-km coastline, 
opportunities in offshore energy have great potential.

3.7. State and Prospects of Wind Power Development 
in Russia
The technical electric power potential of the Russian wind power 
industry is about 17.1 TW/year, which is an order of magnitude 
higher than the amount of electricity generated by all the country’s 
power plants in 2018 (Tulupov et al., 2019; Fedotova, 2019).

Most of the wind zones in Russia are located in the South of 
Russia (Kalmykia, Stavropol and Krasnodar Territories, Rostov, 
Volgograd and Astrakhan region, The North Caucasus Federal 
District), on the sea coasts. The ideal place for building a wind farm 
is the Far East, which has about 30% of the economic potential 
of wind power.

The problems of wind energy in Russia began to be addressed in the 
20s of the last century, when the Central Aerohydrodynamic Institute 
named after Professor N. E. Zhukovsky (TsAGI) first developed 
wind farms and wind turbines for agriculture. However, despite this 
seemingly impressive history, the Russian wind power industry is 
currently still significantly behind the growth rate of the industry 
from other countries of the world (Kushnir, 2013; Bushukina, 2019).

Today, more than 50 wind power producers operate on the Russian 
wind power market, among which the largest players are “Rosatom” 
State Corporation, the Finnish company “FortumCorporation” and 
the Italian group of companies “Enel.”

In 2017, Rosatom’s subsidiary “Novavind” JSC and “Lagerwey,” 
a Dutch wind turbine manufacturer, established a joint venture 
called “RedWind,” which is responsible for turnkey deliveries 
of wind turbines and their after-sales service. Another subsidiary 
of Rosatom group, JSC “VetroOGK,” is responsible for the 
construction of the wind farm. The latter company plans to build 
four wind farms in the Stavropol territory with a total capacity of 
260 MW at a cost of 26 billion rubles.

In 2017 The Ministry of Energy of Russia held a competition 
to select renewable energy projects, as a result of which the 

Investment Fund for wind energy development, created by 
“Fortum Corporation” and “Rosnano,” received the right to build 
a wind power plant with a total capacity of 1000 MW. The result 
was the launch in the Ulyanovsk region of the country’s first 35 
MW wind farm connected to the wholesale market. As part of this 
project, the main manufacturer of wind generators, the Danish 
company “Vestas Wind Systems A/S,” will create enterprises on 
the territory of Russia for the production of components for wind 
generators, the first of which, located in Ulyanovsk, will specialize 
in the production of wind turbine blades (Vestas Manufacturing 
Rus) (Lopatkin et al., 2019; Alekseev and Afanasev, 2020).

In early 2018, PJSC “Enel Russia,” controlled by “Enel,” signed 
an agreement to build a wind power plant in the Rostov region 
with a capacity of 90 MW and in the Stavropol Territory with 
a capacity of 300 MW. The international concern “Siemens 
Gamesa,” which specializes in the production of wind turbine 
generators, will supply equipment and then localize production 
for future wind farms. The start of commissioning of the wind 
farm is planned for 2020.

To date, Russia has 11 large wind farm with a capacity of over 1 
MW, 8 wind power <0.1 MW and the project more than 20 wind 
farms, mainly intended for placement in the southern regions 
of the country. The most powerful wind farm in Russia today 
is considered to be the Ulyanovsk WPS-1. It includes 14 wind 
turbines with a total capacity of 35 MW with an annual sales 
volume of about 85 GWh.

4. CONCLUSION

According to a report entitled “the Future of Wind,” presented on 
October 21 at the China Wind Power event in Beijing, by 2050, the 
world’s wind power could grow tenfold and cross the threshold of 
6,000 GW. By the middle of the century, wind power could meet a 
third of the world’s electricity demand and, combined with further 
electrification, reduce the carbon emissions generated by the 
energy industry by a quarter, which is necessary to meet the terms 
of the Paris Agreement. To achieve these goals, it is necessary to 
increase wind power capacity on land and at sea by four and ten 
times, respectively, compared to the existing ones.

The bet on renewable energy is correct. For the state, wind farms 
are not just an object of generation, but also the development of 
new technologies, the creation of additional jobs, and the growth of 
orders for equipment. The global wind power industry can become 
a true driver of job creation, providing employment for more than 
3.7 million people by 2030 and more than 6 million by 2050. These 
figures are almost 3.5 times higher, respectively, than the number 
of jobs that make up just over a million in 2018. Sound industrial 
and labour policies that build on and strengthen domestic supply 
chains can help increase income and employment by attracting 
existing economic activities to support wind energy development.

As for the prospects for the development of this market in the 
regional context, the authors believe that Asia can increase the 
installed capacity of its own onshore wind power from 230 GW 
in 2018 to more than 2600 GW by 2050. By this time, the region 



Linnik, et al.: Wind Power: Current State and Perspectives

International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 2020 79

will be a world leader in wind power, accounting for more than 
50% of all onshore installed capacity and more than 60% of all 
the offshore capacity.

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