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International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 2020502

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), 502-509.

Basic Stages of Energy Development Program Implementation in 
the Chechen Republic

I. A. Kerimov*, M. Sh. Mintsaev, M. V. Debiev, M. Ya. Pashaev

Grozny State Oil Technical University named after Acad. M.D. Millionshchikov, Grozny, Russia. *Email: i.akerimov@yahoo.com

Received: 24 June 2020 Accepted: 11 September 2020 DOI: https://doi.org/10.32479/ijeep.10492

ABSTRACT

The article discusses the issues of energy complex development of the Chechen Republic, which requires the creation of a stable multi-vector energy 
that can satisfy the growing needs of the population and economy of the region. The main emphasis is made on the development of the renewable 
energy sources, which need to be paid close attention, drawing on the experience of other entities and countries developing innovative technologies 
in this direction. The analysis of the energy development program implementation in the Chechen Republic (2011-2030) over the past 8 years has 
been carried out, which includes four subprograms describing the potential of resources and the prospects for the energy development in the Chechen 
Republic,. The estimation of power consumption indicators and maximum loads in the Chechen Republic until 2018 and for the long term (“calculated,” 
“optimistic” and “actual” options) is given. The analysis of the state and potential for the water energy development in the Chechen Republic is carried 
out. The analysis of natural resources potential of the republic is carried out in order to implement effectively and develop each of the considered 
renewable energy sources, taking into account the development of modern innovative technologies to reduce electrical energy consumption. The state 
estimation of the existing integrated power grid of the Chechen Republic is given, where the initial tasks of work coordination to improve the efficiency 
of the republic’s energy system are outlined. The results of total indicators of electric grid construction and facilities reconstruction for 2011-2019 
are derived. Possible directions (calculated and optimistic options) of the electrical energy industry development are considered. In order to develop 
successfully the energy sector of the Chechen Republic, taking into account the electrical energy load growth, the development of modern program for 
the of alternative and renewable energy sources development was proposed that will allow to create additional electrical energy sources in combination 
with traditional ones. At the same time, the implementation of fundamental and applied research in the field of renewable energy was proposed.

Keywords: Electric Energy Industry, Power System, Power Center, Electric Energy, Power Balance, Alternative and Renewable Energy Sources 
JEL Classifications: O13, P28, P48, Q42, Q43, Q47, R11

1. INTRODUCTION

The energy sector is one of the foundations for the development of 
the economy of both the region and the country as a whole. After 
a sharp decline in energy production in the early nineties, the level 
of energy sources production and consumption began to increase. 
However, there are a number of serious problems which if are not 
solved, the level of developed countries is impossible to reach. The 
irrational structure of the energy complex, where the use of gas 
and oil predominates, the considerable depreciation of equipment 
and electric transmission lines, the backwardness of technologies 
and low efficiency compared to today and high costs associated 

with this, lack of available funds for the retrofit and development 
of energy sector are аmong these problems. That’s why, raising of 
efficiency of energy sources use, adoption of new advantageous 
alternative sources, the need to find new solutions that take into 
account regional characteristics, is one of the most important tasks 
in the energy sector development. The search for ways out of the 
described difficult situation requires a comprehensive analysis 
of all factors affecting the regional energy development process 
(Burmistrov, 2009; Al-Falahi Monaaf, 2017; Palival, 2014.).

The development of the region’s energy capacities is a detailed study 
of the object of research on factors that affect the energetic state of 

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



Kerimov, et al.: Basic Stages of Energy Development Program Implementation in the Chechen Republic

International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 2020 503

the region as a whole. To perform an analysis of energy development 
schemes, first of all, it is necessary to identify all the base entities that 
affect the region’s energy sector formation and development, that is, the 
main “global participants” in the region’s energy sources production 
process. Those are: directly existing power system; the economy, 
primarily industry, which is the main consumer of energy sources and a 
supplier of material resources (equipment, raw materials) to the energy 
system; the population, which is also one of the important consumers 
of energy resources; personnel in the energy production system, the 
environment, and the state, including regional authorities. Based 
on the analysis of the factors, it is necessary to develop schemes of 
possible ways of the region’s energy system formation and functioning 
(Guardian, 2017; Sibikin and Sibikin, 2010).

2. METHODS

In order to ensure a stable economy of the Chechen Republic 
with energy resources, a scientifically based state energy policy is 
required. First of all, the Chechen Republic Energy Development 
Program for 2011-2030 was developed for this in 2010, in which 
the principal directions and critical parameters, the list and terms 
of the electric power facilities planned for construction and 
commissioning were considered (Debiev and Popov, 2012).

This program is reviewed annually and appropriate adjustments 
are introduced. The program is a document that defines the goals, 
main objectives and directions of the longstanding program for 
the development of the energy complex of the Chechen Republic, 
taking into account emerging internal and external issues in the fuel 
and energy sector, as well as in the economy of both the Chechen 
Republic and the Russian Federation as a whole.

The energy development program of the Chechen Republic, taking 
into account the development of the electrical energy complex for 
the period until 2030, includes 4 subprograms:
•	 Subprogram “Electrical energy.”
•	 Subprogram “Water energy.”
•	 Subprogram “Use of alternative and renewable energy sources.”
•	 Subprogram “Use of geothermal waters.”
• Moreover, two programs have been developed additionally 

to increase the reliability of the functioning of the integrated 
power grid of the Chechen Republic:
•	 The Chechen Republic electric grid complex modernization 

and reliability improvement program for 2020-2024 
(long-term), which covers modernization, technical re-
equipment, renovation and new construction of power 
lines with a length of 5,188 km and the transformer fleet 
with capacity of 577 MVA;

•	 The program to reduce electrical energy losses for 2019-
2023, for the retrofitting and reconstruction of 10-6/0.4 kV 
transformer substations with outgoing 0.4 kV overhead 
lines, as well as with the construction of 6.10 kV branch 
lines from overhead lines.

2.1. Subprogram “Electrical Energy”
Currently, the management and operation of the energy complex of 
the Chechen Republic is carried out by the distribution company 
- JSC Chechenenergo. This complex territorially includes electric 

power systems with voltage of 330 kV, as well as electric power 
systems with voltage of 0.4; 6; 10; 35; 110 kV (Kerimov and Debiev, 
2012). Today the most important and primary main substation for the 
110 kV electric power system on the territory of the Chechen energy 
system is the substation “Substation 330 kV Grozny.” In 2011, the 
third autotransformer - “AT-3 330/110 kV” was installed on the 
substation “PS 330 kV Grozny” with subsequent commissioning 
with a total capacity of 125 MVA and the total power of the 
substation is 375 MVA. The electric power systems with voltage 
of 330 kV are owned by JSC “FGC UES” and are serviced by its 
regional branch - Main Power Transmission Lines of the South. The 
electric power systems with voltage of 0.4; 10; 35 and 110 kV are 
mainly owned and operated by JSC “Chechenenergo.”

JSC “Chechenenergo” is the electricity wholesale market entity, as 
well as a guaranteeing electrical energy supplier serving consumers in 
six cities (Grozny, Gudermes, Kurchaloy, Argun, Shali, Urus-Martan) 
and 16 rural areas of the Chechen Republic. JSC “Chechenenergo” 
serves 200 thousand individuals and 16 thousand legal entities.

JSC “Chechenenergo” has the following technical potential on the 
books - the number of substations is 4928 pcs., including:
•	 30 substations of 110 kV;
•	 59 substations of 35 kV;
•	 4842 substations of 6-10 kV.

The total transformer capacity of all substations is 2258.96 MVA.

The length of electric transmission lines is 14678.31 km, including:
•	 Overhead line 110 kV - 52 pcs. (1,150.54 km);
•	 Overhead line 35 kV - 88 pcs. (980.65 km);
•	 Overhead line 6-20 - 355 pcs. (4,798.85 km);
•	 Overhead line 0.4 - 7408 pcs. (7,748.27 km);
•	 Cable line 6-20 kV - 441 pcs. (459.62 km);
•	 Cable line 0.4 kV - 449 pcs. (644.95 km).

JSC Chechenenergo pursues a uniform technological policy aimed 
at technical development, improving the reliability and efficiency 
of permanent assets.

For the successful development of the electrical energy industry in 
the Chechen Republic, the following tasks are primary (Ellabban 
et al., 2014; Farkhutdinov and Cherkasov, 2017; Palival, 2014):
•	 Ensuring a reliable supply of electrical and thermal energy to 

consumers in the Chechen Republic;
•	 Maintaining full process management of the energy system 

in conjunction with the unified energy system of the Russian 
Federation in accordance with market conditions;

•	 Coordination of work to increase the efficiency of functioning 
and ensure stable development of the energy industry based 
on modern innovative technologies;

•	 Reduction of the level of negative impact on the environment.

3. RESULTS AND DISCUSSIONS

The evaluation of energy consumption indicators and maximum 
loads in the Chechen Republic until 2019 and for the long term is 
shown in 2 diagrams (Figures 1 and 2).



Kerimov, et al.: Basic Stages of Energy Development Program Implementation in the Chechen Republic

International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 2020504

system are a prime consideration (Kerimov and Debiev, 2012).

The development of generating sources in the Chechen Republic 
was provided by enhancement of the Argun TPP to 50 MW and the 
construction of the Grozny TPP with a capacity of 400 MW. The 
commissioning of the Argun TPP capacity was planned in 2019, 
but due to the construction of the Grozny TPP with a capacity of 
358 MW, implementation of measures for the restoration of the 
Argun TPP was completely stopped due to the lack of an investor 
and the advisability of restoring the station in its current form. 
In 2018, the Grozny TPP (GTP-1 and GTP-2, with a capacity of 
176 MW each) was commissioned in the Chechen Republic with 
a total capacity of 352 MW.

Taking into account the commissioning of the second 200 MW 
block at the Grozny TPP and the hydroelectric power chain on 
the Argun river the Chechen energy system can self-balance 
(deficit in capacity is 50-60 MW, in electrical energy - 140-
150 million kW/h). With the commissioning of the 1st and 2nd 
stage of the hydroelectric power chain of Argun HPPs, electrical 
energy excesses increase to 400 million kWh. In the period 
2021-2030 taking into account the commissioning of the third 
stage of the Argun cascade of hydroelectric power stations in the 
energy system of the Chechen Republic, there will be insignificant 
surpluses in both capacity and electricity (up to 130 MW and 470-
480 million kW/h, respectively).

In 2015 a small HPP on the Argun River (SHPP Kokadoy) with 
a capacity of 1.3 MW was commissioned. The construction of a 
small HPP on the Sunzha river with a capacity of 0.5 MW (Kirov 
SHPP) is being completed. Projects for the construction of small 
HPPs on the Argun river have been developed: SHPP “Satellite” – 
1.2 MW; SHPP “Gukhoi” – 2.1 MW; SHPP “Ushkaloy” – 4.9 MW. 
LLC “Yug-Stroy” began investing in construction project of SHPP 
with capacity of 1 MW on the Aksay River with a preliminary cost 
of 294 million rubles.

Preliminary surveys of the LLC “Stroyproject-TM” on the 
construction of the Bashennaya SHPP in the Itum-Kali district of 
the Chechen Republic with an installed capacity of 8 MW and an 
estimated value of 1.3 billion rubles have begun.

According to the Energy Development Program of the Chechen 
Republic for 2011-2030 on the Terek ridge of the republic, it was 
planned to build a wind farm consisting of 24 WDPPs with an installed 
capacity of 1.5 MW each, with the total installed capacity of 36 MW.

Unfortunately, this project is currently not taken into account in 
the program (Debiev and Popov, 2012). The Government of the 
Chechen Republic signed an agreement with LLC “Avelar Solar 
Technology” on the construction of a solar power plant in the 
Chechen Republic with a capacity of up to 5 MW with an estimated 
construction cost of 525 million rubles.

3.2. Electrical Power Systems Development
Analyzing the state of the energy complex of the Chechen 
Republic, it is necessary to outline the following initial tasks for 
the development of electrical power systems:

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Figure 1: Maximum power diagram

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Figure 2: Electrical energy consumption diagram

In 2019, the Chechen energy system’s own maximum load amounted 
to 492 MW (Figure 1), as a result the rate of electricity consumption 
has a dynamic of a certain growth in electricity consumption. In 
the Chechen Republic, as a result of infrastructure development, as 
well as continued construction and repairing works, compared to 
2018, the level of energy consumption increased by 5% and reached 
the value of 3015.9 million kW/h. (Figure 2). At the same time, 
due to the fact that the existing electric networks are overage and 
have not undergone renewal, the losses of electrical energy occur, 
which must be minimized by renewal of the electric power systems. 
The main goal of electricity losses reduction is the implementation 
in the territory of the Chechen Republic of the Comprehensive 
program to reduce excess losses. Moreover, the active work of 
energy supplying enterprises in relation to consumers is required 
to obtain the effect of electricity losses reduction and increasing 
the level of payments for electricity consumed.

3.1. Development of Power-supply Sources, Capacity 
and Electrical Energy
The shortage of capacity and electrical energy will increase in the 
coming years and may amount to 500-510 MW in capacity and 
3120-3210 million kW/h in electrical energy in 2020. To achieve the 
goals of power-supply sources development in the energy system 
of the Chechen Republic, the creation of new generating capacities 
and the corresponding modernization of fixed assets of the energy 



Kerimov, et al.: Basic Stages of Energy Development Program Implementation in the Chechen Republic

International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 2020 505

•	 Increasing the stability of electrical connections of the energy 
system of the Chechen Republic with energy systems of other 
regions and constituent entities of the Russian Federation;

•	 The formation and strengthening of the internal electric 
network of the energy system, if necessary, with the possibility 
of electric grid facilities redundancy, the purpose of which 
is to increase the reliability and uninterruptedness of power 
supply to consumers;

•	 Deloading of the 35 kV electric network, which has been 
significantly loaded in recent years and has led to an increase in 
the loss of electric energy in the electric network, additionally 
ensuring the maximum redundancy level with the minimum 
total length of electrical energy transmission lines;

•	 Increase in the transformers’ rated capacitance at some 
substations with a voltage of 35 and 110 kV, the load of which 
in recent years has increased and reached 70-90% of their 
rated capacitance, as a result they are overloaded at 
load-peaks;

•	 Making decisions on the construction, reconstruction 
and retrofitting of some overhead transmission lines and 
substations that have exhausted performance potential;

•	 Improving the flexibility of substation circuits and overhead 
transmission lines, replacing primary switching equipment 
in order to increase the reliability of both the energy system 
itself and the electric power supply to consumers.

Over the past 4 years, six new substations with voltage of 
110 kV and total capacity of 285 MVA have been constructed and 
commissioned on the territory of the republic. The “110 kV City” 
substation, built in the center of Grozny and put into operation in 
2019, with two transformers of 40 MVA each, with a total capacity 
of 80 MVA, is one of the first digital substations in the North 
Caucasus. This substation will allow removing electrical loads 
from overloaded substations in the city of Grozny and thereby 
will act to raise the uninterruptibility, reliability and quality of 
electric power supply to the population and infrastructure of the 
capital of the Chechen Republic. Replacement of one of the two 
transformers from 16 MVA to 40 MVA was performed at the 
substation “110 kV Shali” substation, which also contributes to the 
uninterrupted operation, reliability and quality of electric power 
supply to the population and infrastructure completely of the 
Shali and Vedeno regions of the republic. The block transformers 
with a capacity of 250 MVA (total - 500 MVA) are installed at 
the commissioned Grozny TPP. An increase in the capacity of the 
transformer fleet of the existing substations of the Chechen energy 
system by 245 MVA was performed. Five overhead transmission 
lines with a voltage of 110 kV were commissioned, the total length 
of which is about 120 km. The reconstruction and retrofit of some 
substations of JSC “Chechenenergo” was carried out, with the 
replacement of switching equipment, as well as the installation 
and commissioning of relay protection and automation devices 
on a modern elemental base.

In view of the fact that the limited possibilities for innovative 
development of the energy complex are observed in the regions, 
it is necessary to analyze the effectiveness of the introduction and 
development of renewable energy sources, taking into account 
the development of modern innovative technologies that reduce 

energy consumption (Burmistrov, 2009; Ellabban et al., 2014; 
Palival, 2014).

4. SUBPROGRAM “WATER ENERGY”

Today the state of Russia’s water energy complex consists of over 
80 hydropower plants with a total installed capacity of about 46 
thousand MW. The long-term annual average generation reaches 
180 billion kW/h/year, which is 22% and 18.6% respectively, 
of capacity and generation from all the existing power plants 
of the Russian energy system. This list does not include small 
hydropower plants (HPPs). The advisability of using the water 
energy resources of mountain rivers has been justified repeatedly 
on the practical activities of the energy development in the 
republics of the North Caucasus, where 36 hydropower plants are 
operating currently. Works on the design and construction of about 
30 more hydroelectric power stations are under way (Guardian, 
2017; Kerimov and Debiev, 2012).

In the “Layout of hydroelectric power chain and social sphere 
facilities” presented by “RIKO Group,” the construction of a 
hydroelectric power chain on the Argun river which plans to ensure 
in the Chechen Republic: the further development of the economy, 
agricultural facilities, the production of ecologically-green 
electrical energy, the improvement of services and recreation, 
reduce losses in electric networks, improve the social situation. In 
August 2015 a small hydroelectric power station with capacity of 
1.3 MW was commissioned on the river Argun. The Government 
of the Chechen Republic and RAO “UES of Russia” earlier came 
to a mutual decision on the necessity to develop water energy. By 
the Resolution of the Chechen Republic Government in 2009, the 
construction project of hydroelectric power chain on the Argun 
river was included in the List of priority investment projects and 
proposals of the Chechen Republic. In general, the investment 
project of the Argun hydroelectric power chain is also of great 
social importance, associated with the creation of more than 20,000 
new jobs during construction (12-15 years).

The territory of the Chechen Republic is characterized by a 
high supply of water resources (both surface and underground), 
concentrated in rivers, lakes, water storage reservoirs, glaciers 
and in the earth interior. The whole territory of the republic is 
characterized by an arterial drainage. The number of all rivers is 
about 3198, the total length of which is 6508.8 km. Heavy autumn 
rains in the mountains also contribute to water level rise in the 
rivers of the republic. The value of the water level in mountain 
rivers is minimum in winter. The flow of mountain rivers by 
the seasons of the year is characterized by approximately the 
following distribution coefficient: 55% for the summer period 
(June-August), 35% for the spring and autumn, and 10% for the 
winter (December-February). The hydrological regime of rivers 
of this nature contributes to favorable conditions for irrigation of 
the soil, but is adverse for the regular operation of hydroelectric 
power plants. It should be noted that the hydrological regime of the 
rivers of the republic has changed significantly in recent decades, 
and therefore it is necessary to conduct regular hydrological 
observations on the most of rivers of the republic (Kougias and 
Patsialis, 2014; Morales and Corredor, 2014).



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International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 2020506

5. SUBPROGRAM “ALTERNATIVES AND 
RES”

5.1. Wind Energy
Wind power continues to be the largest segment of the renewable 
energy market over the past few years. The total capacity of all 
wind turbines in the world amounted to about 530 GW at the 
end of 2017, which was almost one and a half times higher than 
the total capacity of 439 nuclear power reactors registered in 32 
countries of the world with a total capacity of 340 GW. So, in 
2017, 52 GW capacity from wind turbines was commissioned in 
the world, which was absolutely unprecedented (Al-Falahi, 2017; 
Barinova and Lanshina, 2017).

Concrete calculations for the research and study of wind energy 
resources in the Chechen Republic were not carried out. The 
Chechen Republic belongs to the region, where the territory is 
characterized by the medium speed of wind energy. A certain 
feature of the republic’s wind potential is the irregularity in the 
distribution of wind speed over different districts and intensity in 
different periods of the year. One of the most common types of 
winds in the territory of the Chechen Republic are mountain and 
valley breezes arising due to different air temperatures of particular 
areas of valleys or hollows, as well as flanks. The directions of 
the mountain and valley breezes are characterized by a day shift. 
Also, the mountain and valley circulation is expressed especially 
strong and reaches its maximum value in the summer season 
(Farkhutdinov and Cherkasov, 2017; Kerimov and Debiev, 2012).

The certain calculations of the wind potential have been performed 
for some different climatic zones of the republic, namely, the 
mountainous terrain, the midland and the Zaterechny plain, with 
the recalculation of wind speeds and frequencies and intensities 
from the height of weather vanes to a height of 75 m (the level 
of the upper point of a wind power plant with a capacity of 500-
750 kW). From the analysis of the calculations, it follows that 
the wind energy gross potential of the above territories is 1406.0 
billion kWh/year, and the technological capacity, in turn, reaches 
≈ 14.0 billion kWh/year. Therefore, in some areas of the republic 
where the wind speed is quite high, the use of wind energy is 
an innovative solution. The use of modern wind-driven power 
plants (WDPPs) is economically feasible and profitable with an 
average annual wind speed of 5 m/s (Kerimov and Gaisumov, 
2011; Morales and Corredor, 2014).

Data on wind speeds testify to the development of wind energy in 
the north of the republic. It seems optimal to create a wind power 
plant on the Terek ridge with altitudes of 400-600 m above sea 
level (Kerimov and Debiev, 2012). According to the studies on 
windpower engineering, wind energy at such altitudes is 5-10% 
higher than wind energy at altitudes of 0-100 m. Nevertheless, 
wind measurements are necessary for this region. It is necessary 
to install masts for a wind speed measurement cycle at the site of 
the future WDPP.

In recent years, the construction of WDPPs, in particular in the 
Rostov Region, has been actively conducted in several regions 
of southern Russia. Within design basis 78 wind turbines of the 

Danish company Vestas with a capacity of 3.8 MW each will be 
placed in total (Kerimov and Debiev, 2012).

5.2. Solar Energy
Geographically, the Chechen Republic is located between 42° and 
46° north latitude, causing the heavy influx of solar radiation. The 
capacity of solar energy, expressed by the value of the radiation 
balance, in the plain and submontane districts amounts for 50-
55 kcal/cm2/year. The higher the terrain elevation, the lower the 
radiation balance and at an altitude of 2500 m its values do not 
exceed 30-35 kcal/cm2, and in the high mountain zone it decreases 
to negative values and at an altitude of more than 3000 m is –3 
÷ 4 kcal/cm2 on average. On the plain part of the territory of the 
Chechen Republic, the radiation balance is positive for almost the 
entire year. With territory height increase in the winter season, the 
expenditure side of the balance begins to exceed the incoming one. 
The wide scale of the physical and geographical states variety of 
the republic determines the vast diversity in the distribution of the 
sunshine duration (Kerimov and Debiev, 2012).

The sunshine duration averages 330 days a year and the density 
of solar radiation reaches about 0.33 kW/m2 in the entire territory 
of the Chechen Republic, and reaches 0.46 kW/m2 on the plain 
and in mountainous districts. At the same time, there are sunless 
days, which range from 34 to 40 days in the valley and submontane 
districts of the republic and from 10 to 12 days in the mountainous 
areas. The largest number of sunless days is observed on the flat 
part of the territory of the republic and is 61 days. The least of 
“sunless” days in the annual cycle can be seen in the winter, from 
6 to 12 days. From 1 to 5 “sunless” days are observed from the 
end of May to the end of September. In general, over the year 
cloudy weather decreases direct beam radiation by 20 ÷ 25% of 
the potentially probable.

The value of the total solar radiation is determined by the total 
influx of direct and diffuse radiation to the horizontal surface 
of the entire territory of the Chechen Republic. The total solar 
radiation on the republic territory reaches the maximum intensity in 
May-July, varies from 280 to 300 mJ/m2 for submontane districts, 
and ranges from 360 to 400 mJ/m2 in high-mountain districts.

The total volume for the entire territory of the Chechen Republic 
is estimated at 1.365 kWh/(m2∙year). Recently, in view of 
technological upgrade, the efficiency factor of solar panels is 
becoming higher and the energy conversion efficiency of silicon 
photovoltaic sources series-produced by the industry is 12-17%.

It can be said that given the current level of technology development 
and the lack of state support, it is economically feasible to install 
solar stations only in areas where technical means do not allow 
this to be done with the help of other power plants (Barinova, 
2017; Kerimov and Gaisumov, 2011).

5.3. Expander-generator Sets
For the purposes of energy saving during the production of 
electrical energy, in addition to the recovery of waste-heat from 
gas turbine engines, the utilization of the excess pressure of natural 
gas supplied through gas pipelines to the gas distribution station or 



Kerimov, et al.: Basic Stages of Energy Development Program Implementation in the Chechen Republic

International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 2020 507

gas distribution point of compressor stations and large enterprises 
has recently become very relevant. as well as a thermal power 
plant and combined heat and power plant.

Developing technologies for small energy, as well as the creation 
of own generating, autonomous energy sources on the basis of 
high-performance turbo-expander units with electric capacity of 
0.5-10 MW, in different districts, human settlements and industrial 
facilities contribute to the economically sound and prospective 
development of the energy complex (Aldo and Hansen, 2020; 
Kaja and Slabe-Erker, 2020).

Gas is supplied and distributed in the Chechen Republic by the gas 
supplying organization - OAO Chechengazprom. The total length 
of high-pressure gas pipelines is currently 698 km. From 2000 to 
2008, more than thirty gas control stations (GDS) were restored 
and built. Gas consumption in 2009 amounted to 3.1 billion m3.

The energy resource potential of pressurized gas consists of the 
following parameters: gas pressure at the inlet and outlet of the 
pipeline; efficiency factor of a turbo-expander; value of gas flow 
rate and thermodynamic characteristics. The total value of the 
potential of the available gas capacity at the gas distribution 
station of the Chechen Republic is estimated at 27.2 MW. With 
this value of gas it becomes possible to generate electrical energy 
in the amount of 220 to 250 million kWh/year and will largely 
depend on the mode and specific character of design of the applied 
diagrams and operation algorithm.

The employees of the company ZAO “Ion Exchange Technologies” 
(Moscow) performed an analysis of the possibilities of introducing 
an energy-saving complex based on an ETDA expander-generator 
set of Russian production.

Studies have determined that expander-generator sets can be 
effectively used at 11 gas distribution stations of the Chechen 
Republic. In 2011-2018 It was planned to introduce the technology 
of expander-generator sets at five gas-regulating stations, which 
would affect the use of irretrievably lost energy of compressed 
gas, with an installed total capacity of 11.3 MW and generation of 
electrical energy up to 100 million kW/h in year. Estimated project 
cost - 500 million rubles. The first project was supposed to be 
implemented in 2011-2012 at GDS-1, with a rated capacity of 1.5 MW 
and electrical energy generation up to 13.1 million kW/h/year. The 
estimated cost of the project is 62.1 million rubles.

Currently, the team of the scientific and technical center (STC) 
“Green Energy” has developed proposals for the introduction 
of expander-generator set at the Chir-Yurt cement plant, which 
will significantly increase the energy supply of technological 
production.

5.4. Bioenergy
The issues of solid municipal waste (SMW) utilisation in bioenergy 
in the Chechen Republic have not been raised before, however, it is 
known from international experience that the level of profitability 
of biogas production increases significantly when waste utilisation 
from cities with a population of more than 100 thousand people and 

preparation for production is carried out in advance at the stage of 
filling of the Municipal solid waste landfills. The implementation 
of such production is possible in some cities of the Chechen 
Republic; Grozny, Gudermes, Argun, Shali, Urus-Martan, etc. 
(Kerimov and Debiev, 2012; Morales and Corredor, 2014).

The evaluation of initial biogas utilization, at the Municipal solid 
waste landfill of Grozny, is given below.

5.4.1. Engineering factors
•	 The value of biogas obtained is 13-15, 0 thousand m3/day. 

(5.0 million m3/year);
•	 Reduction of GHG emissions: about 40 thousand tons of CO2 

- equivalent/year;
•	 The design capacity of the engine generator, which can be 

used to generate electrical energy from biogas is 1000 kW;
•	 Tariff of electricity sold - 1.74 rubles./kWh;
•	 Discount rate - 10%;
•	 The cost of a unified social tax (UST) is 8 euro/t СО2 - eq.

The cost of construction of the biogas collection and utilization 
system in developed countries is usually in the range of $ 1,550-
2,250/1 kW of installed electric capacity. In accordance with the 
Kyoto Protocol, as a result of biogas collection and utilization, 
the so-called “carbon credits” or “emission reduction units” can 
be carried out as part of joint implementation projects. As a result, 
one can get additional investment of approximately $ 0.02/kWh 
(0.62 rubles KWh). This possibility increases significantly the 
attractiveness of biogas utilization even at the landfills that were 
previously considered prospect less. The average payback period 
of the project for landfill gas utilization for electricity production 
without taking into account the sale of Emission Reduction 
Units is 7-8 years, and taking into account the sale of Emission 
Reduction Units is <3 years. For the domestic waste recovery 
with biogas production at existing landfills in large cities and 
the human settlements of the Chechen Republic, it is necessary 
to conduct research on the domestic waste potential assessment, 
determine the direction of utilization and develop the project 
feasibility study for the implementation of technology. To solve 
these problems, in 2011 it was planned to allocate 10.0 million 
rubles for the research works.

6. SUBPROGRAM “MULTIPLE USE OF 
GEOTHERMAL WATERS”

More than 70% of the geothermal water reserves of the Russian 
Federation are located on the territory of the North-Caucasian 
Federal District. Among the constituent entities of the Russian 
Federation the Chechen Republic ranks third in terms of explored 
geothermal water reserves, trailing only to Dagestan and the 
Kamchatka region. On the territory of the Chechen Republic there 
are the most favorable conditions for the creation of geothermal 
circulation systems, which is confirmed by the long-term operation 
of the first geothermal circulation system in the USSR created in 
the Khankala Valley in 1985 (Kerimov and Gaisumov, 2017, April 
7). On the territory of the Chechen Republic there are 14 thermal 
intakes, according to which the total explored reserves amount 



Kerimov, et al.: Basic Stages of Energy Development Program Implementation in the Chechen Republic

International Journal of Energy Economics and Policy | Vol 10 • Issue 6 • 2020508

to 64,680 m3/day in spouting mode. The reserves for commercial 
categories in the amount of 10,650 m3/day are approved for two 
thermal water intakes (Khankala, Goity).

In explored fields, the commercial reserves of geothermal waters 
cannot satisfy the ever increasing demand for heat. For example, 
in 1985 only in Grozny the declared demand for thermal water 
amounted to 78 thousand m3/day. That’s why to satisfy the needs 
of the republic in thermal water, an increase in the raw material 
base is required due to the construction of new thermal intakes 
and expansion of old ones. At present, the main consumer of 
thermal water is municipal infrastructure - 12.8 thousand m3/day 
(48%) and agriculture - 11.4 thousand m3/day (43%). According 
to calculations, the creation of a geothermal heat supply system in 
the territory of Grozny city on the basis of explored resources of 
the fields will ensure annual savings of fossil fuel at 150 thousand 
tonns of fuel oil equivalent and reducing the harmful substances 
emissions into the atmosphere in the amount of 250 thousand tons.

From the available 14 geothermal water deposits, the Khankala 
field is the largest and most promising in terms of commercial 
development, which is characterized by a shallow bedding of 
deposits, large flow rates, high enthalpy, low salinity, and high 
content of valuable components.

Within the Decree of the Government of the Russian Federation 
No. 218 of April 9, 2010, by efforts of GSOTU named after Acad. 
M.D. Millionschikov the comprehensive project was implemented 
to create a experimental-industrial geothermal station based on the 
implementation of the circulation scheme for using the deep heat 
of the Earth (Kerimov and Gaisumov, 2017, April 7). This field 
has several advantages over others:
•	 Bedding of deposits at shallow depths (up to 1000 m);
•	 Large flow rates (up to 1 l/cm);
•	 High temperatures (up to 1000С and more);
•	 The waters of the XIII bed are practically fresh, with salinity 

of 0.81-1.7 g/l, which conditions their low corrosion activity;
•	 The ability to extract valuable components.

The area assigned for the Khankala geothermal station is 4900 
m2, while the area of the station itself, including the wells, is 
406 m2. At the same time, the heat survey of the village. Gikalo 
and the adjacent territory of the Khankala deposit revealed 13 
abnormalities with various sources (bonfires, heating systems, 
etc.). To reduce the formation of solid deposits in the form of 
carbonates, corrosion inhibitors (5 g/ton of treated water) are used 
in the field (Kerimov and Mintsaev, 2019).

7. CONCLUSION

The development of the energy complex of the Chechen Republic 
requires the creation of a stable multi-vector energy that can 
satisfy the growing needs of the population and the economy 
of the region, and renewable energy sources need to be given 
close attention, drawing on the experience of other entities and 
countries developing innovative technologies in this direction. 
The primary tasks of the development of the republic’s energy 
sector are as follows:

1. Development of the modern program for the development 
of alternative and renewable energy sources in the Chechen 
Republic.

2. Organization of hydrological monitoring on the mountain rivers 
of the republic in order to select the optimal locations for SHPP.

3. Organization of integrated meteorological observations (solar 
radiation, wind speed and direction at different heights, etc.) in 
various districts of the republic in order to select the optimal 
locations for solar and wind power plants.

4. Implementation of fundamental and applied research and 
development in the field of renewable energy.

5. Development of recommendations and investment proposals 
for industrial enterprises and housing and communal services 
of the republic.

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