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Engineering, Technology & Applied Science Research Vol. 9, No. 2, 2019, 4019-4026 4019  
  

www.etasr.com Nguyen et al.: Green Scenarios for Power Generation in Vietnam by 2030 

 

Green Scenarios for Power Generation in Vietnam by 
2030 

 

Vu H. M. Nguyen  

Faculty of Electrical and Electronics Engineering 
Ho Chi Minh City University of Technology and Education 

Ho Chi Minh City, Vietnam 
vunhm.ncs@hcmute.edu.vn 

Cuong V. Vo 

Faculty of Electrical and Electronic Engineering 
Ho Chi Minh City University of Technology and Education 

Ho Chi Minh City, Vietnam 
cuongvv@hcmute.edu.vn 

Luan D. L. Nguyen 

Department of Urban Engineering  
Ho Chi Minh City University of Architecture 

Ho Chi Minh City, Vietnam 
luan.nguyenleduy@uah.edu.vn 

Binh T. T. Phan 

Faculty of Electrical and Electronics Engineering 
Ho Chi Minh City University of Technology 

Ho Chi Minh City, Vietnam 
thanhbinh055@yahoo.com 

 

 

Abstract—Energy for future sustainable economic development is 

considered one crucial issue in Vietnam. This article aims to 

investigate green scenarios for power generation in Vietnam by 

2030. Four scenarios named as business as usual (BAU), low 

green (LG), high green (HG) and crisis have been proposed for 

power generation in Vietnam with projection to 2030. Three key 

factors have been selected for these scenarios, namely: (1) future 

fuel prices, (2) reduction of load demand caused by the 

penetration of LED technology and rooftop photovoltaic (PV) 

systems, and (3) the introduction of power generation from 

renewable sources. The least costly structure of power generation 

system has been found. CO2 emission reduction of HG in 

comparison to the BAU scenario and its effect on generation cost 

reduction are computed. Results show that BAU is the worst 

scenario in terms of CO2 emissions because of the higher 

proportion of power generation from coal and fossil fuels. LG 

and HG scenarios show their positive impacts both on 

CO2 emissions and cost reduction. HG is defined as the greenest 

scenario by its maximum potential on CO2 emission reduction 

(~146.92Mt CO2) in 2030. Additionally, selling mitigated CO2 can 

make green scenarios more competitive to BAU and Crisis in 

terms of cost. Two ranges of generation cost (4.3-5.5 and 6.0-

7.7US$cent/kWh) have been calculated and released in 

correspondence with low and high fuel price scenarios in the 

future. Using LED lamps and increasing the installed capacity of 

rooftop PVs may help reduce electric load demand. Along with 

the high contribution of renewable sources will make the HG 

scenario become more attractive both in environmental and 

economic aspects when the Crisis scenario comes. Generation 

costs of all scenarios shall become cheap enough for promoting 

economic development in Vietnam by 2030. 

Keywords-green; scenario; least cost; optimum power 

generation; Vietnam 

I. INTRODUCTION  

Energy for sustainable development is one of the most 
crucial issues globally. In long-term energy planning, there are 

many uncertainty factors. In order to address the issue, green 
energy scenarios of IEA, BP, and China have been built which 
are projected to 20-30 years ahead [1-3]. Electricity usualy 
takes a high part of about 25% to 45% of total energy 
consumption. Finding the optimum structure for a power 
system in a competitive market with many constraints of 
transmission lines, the rules of the market constitute a multi-
researched topic [4-8]. 

Vietnam has been considered as one of the most dynamic 
emerging countries with approximately 7% of annual Gross 
Domestic Products (GDP) increase in the last 20 years. That 
development has led to up to 15% increase of the yearly 
nationwide electricity power demand [9]. It is currently a big 
issue of Vietnam, relevant to the lack of primary fuels supplies. 
Another obstacle for power generation in Vietnam to meet the 
mentioned rapid economic development is environmental 
pollution [10]. Summarizing, supplying electricity power to 
meet the development of the economy is one of the most urgent 
issues of Vietnam. Vietnam Electricity Corporation (EVN) is a 
state-owned enterprise which is responsible for the whole 
country. EVN is required to cooperate with other relevant 
energy institutes and departments to prepare and release multi-
scale development plans for the national power system, where 
the periodic master plan which projects the development plan 
for the next 15 to 20 years ahead is expected as the most 
important outcome. The most recent relevant release is decision 
No 428/QD-TTg on March 18

th
 2016 [9]. Three development 

scenarios for Vietnam power system by 2030 have been 
proposed, namely Base, High ratio of renewable energy, and 
High load demand scenarios. However, numerous dubiousness 
regarding historical input data, mathematical functions, and 
results of load demand forecasting have been identified from 
those three scenarios. That vagueness made forecasting results 
of [9]. not verifiable. The shifts in power consumption 
awareness and generation sources have created three new 

Corresponding author: Cuong V. Vo



Engineering, Technology & Applied Science Research Vol. 9, No. 2, 2019, 4019-4026 4020  
  

www.etasr.com Nguyen et al.: Green Scenarios for Power Generation in Vietnam by 2030 

 

factors which have a strong and direct effect on the power 
system: (1) the rapid growth of LED lamp technology, (2) the 
withdrawing of nuclear power from the national electric power 
structure (since June 2016), and (3) the release of Decision No. 
11/QD-Tags on April 14

th
 2017 [11]. The above factors made 

the scenario in [9] become inappropriate. New scenarios with 
updated forecasting objectives by 2030 must be studied and 
introduced to fulfill [9]. 

The purpose of this paper is to propose two state-of-the-art 
concepts of green power generation scenarios for Vietnam 
power system by 2030. New concepts are strongly based on: 
the uncertainty of future fuel price, the penetration of LED 
technology and the increasing installed capacity of rooftop PV 
systems, and the difference in proportion of renewable energy 
exploited in Vietnam power system. A least cost objective 
function and its constraints in correspondence with each 
scenario will be established. A software named LINDO (linear, 
interactive, and discrete optimizer) is employed to figure the 
optimum structure of Vietnam power generation system with 
projection to 2030. The scope of the study is the power 
generation system in Vietnam only. The system is not yet 
capable to be put into a whole power system with constraints of 
trasmission lines and rules of a competitive maket. 

II. METHOD  

The scenarios are proposed based on uncertainty factors 
which have strong effects on sources (input) and load demands 
(output) of the power system. An objective function in terms of 
least cost and its constraints is employed to figure the optimum 
structure of Vietnam power generation system.  

A. Power Generation Scenarios 

Three variable key factors have been selected for creating 
power generation scenarios: future fuel price, reduction of load 
demand caused by the penetration of LED technology and 
rooftop PV systems, and the introduction of power generation 
from renewable sources. Table I presents two scenarios of 
Vietnam’s fuel price by 2030. Proposals for the price of two 
common fuels used for power generation in Vietnam (coal and 
gas) are computed. Indicators show that there are big 
differences between the low and high scenarios. Two models 
computed by the two prestigious institutes have approximately 
a difference of 100% [11, 12]. 

TABLE I.  FUEL SCENARIOS 

Fuel price Scenario 2020 2025 2030 

Coal ($/ton) 
High [12]

 
93.5 98.3 103.3 

Low [11]
 

41.8 44.4 48.2 

Gas ($/MBtu) 
High [12]

 
9.2 10.9 11.6 

Low [11]
 

4.9 5.5 5.7 

 

Since the price of LED lamps has been dramatically 
reduced, they are considered as the best choice for replacing 
conventional lamps in existing and new constructions. The 
strong penetration of LED lamps will lead to significant 
reduction of power load demand. Assumptions of lighting load 
share and LED penetration by 2030 are presented in Table II. 
Decision No 11/QD-TTg [11] promoted the installation wave 

of residential rooftop PV systems in the south regions of 
Vietnam. Taking effect since June 1

st
 2017, it was the first 

cornerstone of Vietnam’s regulatory framework to encourage 
the development of solar energy utilization, which has been 
considered as one of the most effective ways to reduce the load 
demand. Assumptions of the rooftop PV systems are shown in 
Table III. Electric load demand scenarios resulted by the 
penetration of LED lamp technology are shown in Table IV. 
The High values are forecasted, while the Low values are 
reduced by the penetration of LED technology from 1.2% to 
6.2% and 1.5% to 8.2%, respectively. 

TABLE II.  ASSUMPTIONS OF LIGHTING LOAD AND LED 

Year 2020 2025 2030 

Lighting consumption (%) [9] 23 21 19 

Capacity factor of lighting 0.75 

Total lighting Pmax (%) [9] 30.7 28.0 25.3 

Penetration of LED (%) 10 30 65 

Energy reduction by LED (%) 50 

TABLE III.  ASSUMPTIONS OF ROOFTOP PV SYSTEMS 

Year 
Residential 

consumption [9] (%) 

Penetration of rooftop PVs (%) 

Low High 

2020 34.75
 

2 2 

2025 31.36
 

10 15 

2030 28.63
 

20 30 

TABLE IV.  ASSUMPTIONS OF LIGHTING LOAD AND LED 

Year 
Demand (TWh) Pmax (GW) 

High [13] Low Reduction (%) High [14] Low Reduction (%) 

2020 230.20
 

227.55 1.2 40.33 39.71 1.5 

2025 349.95
 

338.93 3.2 60.84 58.28 4.2 

2030 511.27
 

479.70 6.2 87.56 80.35 8.2 

 

Considering the combination of the development of rooftop 
PV systems and the penetration of LEDs, an option of deeply 
low load demand is proposed. A concept of cumulative 
reduction is presented in Table V. It is noted that the rooftop 
PVs will take to the reduction of TWh only while Pmax is not 
affected because Pmax normally occurs at evening (at around 
7:00 pm). 

TABLE V.  CUMMULATIVE ELECTRIC LOAD DEMAND REDUCTION 
BY LED AND ROOFTOP PV SYSTEMS 

Year 

Demand 

Low 

(TWh) 

Reduction 

(%) 

Deeply low 

(TWh) 

Reduction 

(%) 

2020 225.97 1.8 225.97 1.8 

2025 328.30 6.2 322.98 7.7 

2030 452.23 11.5 438.50 14.2 

 

Table VI indicates the maximum GWh and MW of power 
generation from renewable sources by 2030 [9]. However, the 
Decision No. 2068/QD-TTg, issued on November 25

th
 2015 

[15] stipulated another option in which the values of 
exploitable renewable sources are much higher than the ones 
presented in Table VI (see Table VII). It is noted that high 
values of biomass are assumed to be reach up to 70% of that in 
[15] only. When combining those above factors, various 
scenarios are generated. Four difference scenarios are proposed 



Engineering, Technology & Applied Science Research Vol. 9, No. 2, 2019, 4019-4026 4021  
  

www.etasr.com Nguyen et al.: Green Scenarios for Power Generation in Vietnam by 2030 

 

and shown in Table VIII: (1) Business as usual (BAU) is 
similar to what happened during the last 5 years in case of low 
fuel price, high load demand, and low sharing of renewable 
energy generation, (2) Low green (LG) represents the case of 
low fuel price, low load demand, and high sharing of 
renewable energy, (3) High green (HG) is generated to perform 
the conditions of high fuel price, deeply low load demand, and 
high renewable energy, and (4) Crisis scenario is the case of 
high fuel price, low load demand and low renewable energy. 

TABLE VI.  SCENARIOS OF LOW RENEWABLE ENERGY [9] 

Generation Unit 2020 2025 2030 

Mini hydro 
TWh

 
11.1 12.4 17.7 

GW
 

3.8 5.2 6.8 

Biomass low 
TWh 2.7 4.8 12.6 

GW 0.5 0.9 2.4 

Wind low 
TWh 2.1 4.0 12.0 

GW 0.8 2.0 6.0 

Solar low 
TWh

 
8.8 12.8 18.9 

GW
 

6.1 8.0 12.0 

TABLE VII.  SCENARIOS OF HIGH RENEWABLE ENERGY [15] 

Generation Unit 2020 2025 2030 

Biomass high 

(70% of [8]) 

TWh
 

8.0 19.2 36.0 

GW
 

1.5 3.6 6.9 

Wind high 
TWh 2.7 6.0 15.4 

GW 1.0 3.0 7.7 

Solar high 
TWh 8.8 23.8 34.3 

GW 6.1 15.0 21.8 

TABLE VIII.  PROPOSED SCENARIOS 

Scenario Fuel price Load demand Renewable energy 

BAU Low High Low 

LG Low Low High 

HG High Deeply low High 

Crisis High Low Low 

 

Vietnam’s economy has been performing well during the 
last 30 years. This boosts the electric load demand and 
therefore sustainable development solutions for energy supply 
must be considered. However, Vietnam’s elasticity of 
electricity demand has still remained at a high value of more 
than 1.7 [9] due to the ineffective implementation of energy 
efficiency policies and frameworks, while the exploitation of 
renewable energy has been neglected. Hence, energy scenarios 
have to be built comprehensively with aim to promote the 
exploitation of renewable energy and to reduce the electric load 
demand. These are the essential conditions to reform a green 
economy for Vietnam. When the price of fuel increases, then 
the load demand must be reduced and renewable energy must 
be considered more seriously. This is a great opportunity for 
developing renewable energy in Vietnam. 

B. Objective Function 

The objective function of the optimal structure for 
generation is the function where the power generation cost is 
minimized in 2020, 2025, and 2030. 

, , , ,

, , ,

. . min= →∑ y g y g q t y
g q t y

O W CE X   (1) 

where g represents the type of generation (hydro, coal, gas, 

mini-hydro, biomass, wind, photovoltaic, import), q is the load 
pattern identified by number 1 to 8 (see Table IX), t is the time 
of a day (from 1:00 to 24:00), y is the considered year (2020, 
2025, 2030), CEg,y is the generation cost of power plant g at 
year y, Xg,q,t,y is the least-cost generation power of power plant 
g, corresponding to the load pattern q at time t of the year y, 
and Wy is the net present value coefficient, calculated by (2): 

2014
1

1 ε

−
+ 

=  + 

y

y

r
W     (2) 

where r is the interest rate, estimated at 8% per year, and ε is 
the inflation rate, estimated at 4% per year. 

The generation cost CEg,y [US$/kWh] of the power plant g 
at year y is calculated by: 

( ), , ,
,

,

+ +
=
∑ g y g y g y

g y

g y

F A MO
CE

Q
   (3) 

where Fg,y is the fuel price, Ag,y is the yearly investment 
depreciation, MOg,y, is the operation and maintenance cost, and 
Qg,y is the power production of power plant g at year y [kWh]. 

The annual investment depreciation Ag,y [US$/year] is 
calculated by: 

( )
( )
0 0 3

, , ,

0

. 1
10

1 1

+
= × × ×

+ −

n

g y g y g yn

r r
A I C

r
   (4) 

where r0 is the ODA interest rate, estimated at 3.8%/year, n is 
the lifetime of the power plant g, [year], Ig,y is the investment 
cost per unit of a power plant g at year y, [US$/kW], and Cg,y is 
the installed capacity of the power plant g at year y , [MW]. 

C. Constraints 

The constraints of the suggested objective function are: 
load demand, upper limit of generation power, reserve power 
capacity, variable limitation of generation power between two 
consecutive hours, and capacity factor. 

1) Load Demand 
In order to meet load demand, it is required for the total 

generation power to be equal with the load power demand: 

, , , , ,
=∑ g q t y q t y

g

X P     (5) 

where Pq,t,y is the load power demand for pattern q at the time t 
of year y. 

2) Maximum Generation Power 
The generation power of power plant g, corresponding to 

the load pattern q at time t of the year y must be lower than the 
maximum generation power of that power plant: 

max., , , , , ,qg q t y g q t y
X X≤     (6) 

where tmax,q is the time that the power plant g operates at 
maximum power, corresponding to the load pattern q. 



Engineering, Technology & Applied Science Research Vol. 9, No. 2, 2019, 4019-4026 4022  
  

www.etasr.com Nguyen et al.: Green Scenarios for Power Generation in Vietnam by 2030 

 

The generation power at the time tmax,q for the load pattern q 
must be lower than the total installed capacity of the power 
plant g in the year y: 

max., , , ,qg q t y g y
X C≤     (7) 

The power production of a power plant g in the year y must 
be lower than the upper capacity limit of that power plant: 

, max. ,g y g y
Q Q≤     (8) 

where Qmax,g,y is the maximum generation power of the power 
plant g in the year y. 

3) Maximum Installed Capacity 
The maximum installed capacity of power generations is 

decided by the upper limitation of input primary energies 
which can be exploited, and the funding sources which can be 
used for constructing new power facilities in certain years. The 
installed capacity of a power plant g in the year y must be 
lower than the maximum installed capacity of that plant at the 
same time: 

, max. ,g y g y
C C≤     (9) 

4) Reserve Power Capacity 
To assure the reliability of the power system, the total 

installed capacity of generation facilities in the year y must be 
higher than the maximum demand power including reserve 
power: 

( ), max.1 .α≤ +∑ g y y yC P    (10) 
where Pmax,y is the maximum power demand in year y, αy is the 
reserve limitation in the year y. 

Reserve power capacity is closely related to the loss of load 
expectation (LOLE) which is chosen as an indicator of power 
system reliability in this study. Values of αy do not include the 
installed capacity of renewable energy sources, i.e. biomass, 
wind, and solar generation. 

5) Capacity Factor 
In each pattern of power load, the diurnal power generation 

of a power plant g must be less than its capacity factor 
multiplied by the theoretical power generation production: 

, , , , ,
24. .≤∑ t g q t y g q g yX L C     (11) 

where Lg,q is the capacity factor of the power plant g 
corresponding to load pattern q. 

6) Limitation of Generation Power Between Two Consecutive 

Hours 
The relation between the probability of changing load 

power demand and the generation capacity of power plant g is 
presented as: 

( ) ( ), , , , , , , , 1,1 . 1 .ρ ρ −− ≤ ≤ +g g q t y g q t y g g q t yX X X  (12) 
where ρg is defined as the limitation of generation power 
variation between two consecutive hours of power plant g. 

III. INPUT DATA COLLECTION 

A. Load Pattern 

Instead of using historical hourly data of power load, 8 load 
patterns, representing 8 typical groups of load profile in a year, 
are employed to minimize calculation time (Table IX [16]). 

TABLE IX.  LOAD PATTERNS OF VIETNAM POWER SYSTEM [16] 

No. Pattern 

1 Tet holidays 

2 W: 1, 2 

3 W: 3, 4, 5 

4 W: 6, 7, 8 

5 W: 9, 10, 11, 12 

6 S & N: 1, 2 

7 S & N: 3, 4, 5, 6, 7, 8, 9 

8 S & N: 10, 11, 12 

W: working day, S: Sunday, N: National holiday 

 

B. Maximum Installed Capacity 

Maximum installed capacities of hydro, mini-hydro, coal, 
and gas generations are officially cited from [8] and [15] (Table 
X). The maximum installed capacities of biomass, wind and 
PV are presented in Tables VI and VII. 

TABLE X.  MAXIMUM INSTALLED CAPACITY (GW) [8, 15] 

Power generation 2020 2025 2030 

Hydro 18.16 18.63 21.22 

Coal 26.71 47.47 65.89 

Gas 9.47 17.55 23.23 

Mini-hydro 3.80 5.20 6.80 

 

C. Reserved Capacity 

Table XI presents the reserve margin and installed capacity 
of Vietnam power system by 2030. It is worth noting that the 
reserved capacity does not include renewable energy sources. 

TABLE XI.  RESERVE MARGIN AND INSTALLED CAPACITY [9] 

Year 

LOLE 

target 

(h/y) 

Reserve 

margin 

(%) 

Demand Pmax 

(GW) 

Installed capacity 

(GW) 

High Low High Low 

2020 24 25 40.33 39.71 50.41 49.64 

2025 24 20 60.84 58.28 73.01 69.94 

2030 24 20 87.56 80.35 105.07 96.42 

 

D. Capacity Factor 

The fact that some power resources depend on climate and 
other natural conditions leads to dependence characteristics of 
capacity factor on natural conditions. For example, the capacity 
factor of a solar power plant depends on the variation of solar 
radiation, the capacity factor of a wind farm may be affected by 
the changes of wind speed, and the capacity factor of a hydro 
power plant will vary when the water flow alters. Therefore, it 
is required to verify the exact capacity factor of each type of 
energy source before taking them into account. 

 



Engineering, Technology & Applied Science Research Vol. 9, No. 2, 2019, 4019-4026 4023  
  

www.etasr.com Nguyen et al.: Green Scenarios for Power Generation in Vietnam by 2030 

 

1) Solar Power Plant 
In order to identify the capacity factor of a solar power 

plant, three important constraints must be accounted for: 

• Sunny time: useful solar radiation could only be collected 
from 6:00 to 18:00. The other times, there may be some 
frail radiation in some regions but it cannot be used. 

• Radiation intensity: solar radiation intensity varies 
continuously throughout the day. 

• Geographical location: Regions which have stable radiation 
duration are the Central, Highland and Southern of Vietnam 
[17]. 

Therefore, it is recommended that solar power plants should 
be constructed around those regions. Based on the solar 
radiation values of Central and Southern provinces presented in 
[17], the capacity factor of a solar power plant could be 
calculated. Solar radiation of Central coast area, and capacity 
factors of PV power plants are presented in Table XII. 

2) Wind Power Plant 
At the height of 60m above sea level, wind energy could 

only be obtained effectively in Ca Mau, a mountainous 
province of Highland, and some provinces of Central coast area 
[18]. The biggest wind farm of the South East Asia, Tuy Phong 
wind farm, is located in Binh Thuan province. However, 
because of the unstable wind speed, the generation power of 
Tuy Phong has high variations. Based on forecasted wind 
speed [18], the capacity factor of a wind power plant located in 
Vietnam could be computed. Table XII presents the capacity 
factors corresponding to the monthly variation of wind speed in 
Central coastal Vietnam. 

3) Hydro and Mini-Hydro Power Plants 
As mentioned above, generation capacity of hydro and mini 

hydro plants strongly depends on water sources and rainfall. 
Based on historical data involving climate conditions, annual 
average rainfall, and rainfall predictions, along with the 
assumption that there will be no unusual changes in the local 
natural conditions, the capacity factor of a hydro power plant 
could be calculated. Regarding a mini hydro power plant, the 
current national regulations on dam design stipulate a very 
small limitation for height, leading to the result that generation 
power of a mini hydro power plant is closely connected to local 
rainfall. Capacity factors of hydro and mini hydro power plants 
are presented in Table XIII. 

4) Capacity Factors of Other Power Plants 
In theory, coal, gas, and biomass power plants can operate 

throughout the year. However, they need to be maintained 
periodically. It normally takes them at least 30 to 45 days per 
year to stop operating for maintenance or for accidental shut-
down. Therefore, in this research, the capacity factors of coal, 
gas, and biomass generations are proposed to be 0.8, as shown 
in Table XIII. 

E. Limitation of Generation Power Variation Between Two 

Consecutive Hours of a Power Plant 

For solar and wind power plants, the generation ability 
between two consecutive hours totally depends on local natural 

conditions, i.e. wind speed changes or variations of solar 
radiation at different times of a day.  

TABLE XII.  SOLAR RADIATION, WIND SPEED IN CENTRAL COAST 
AREA AND PV, WIND GENERATION CAPACITY FACTORS [17, 18]] 

Month 

Solar Wind 

Solar 

radiation 

(kWh/m
2
.day) 

Capacity 

factor  

[per unit] 

Wind  

speed  

(m/s) 

Capacity 

factor  

(per unit) 

1 3.6 0.32 8.0 0.75 

2 4.8 0.43 7.0 0.56 

3 5.2 0.47 5.8 0.34 

4 5.6 0.50 4.2 0.10 

5 5.2 0.47 5.0 0.19 

6 5.2 0.47 5.7 0.32 

7 5.2 0.47 6.5 0.41 

8 5.2 0.47 6.5 0.41 

9 4.4 0.40 5.5 0.29 

10 4.4 0.40 4.3 0.10 

11 4.0 0.36 6.7 0.44 

12 3.6 0.32 8.0 0.75 

TABLE XIII.  GENERATION CAPACITY FACTORS 

Month 
No. of load 

pattern 
Hydro 

Mini-

hydro 
Wind PV 

Coal, gas, 

biomass 

1 1, 2, 6 0.51 0.20 0.75 0.32 0.8 

2 1, 2, 6 0.48 0.20 0.56 0.43 0.8 

3 3, 7 0.48 0.25 0.34 0.47 0.8 

4 3, 7 0.82 0.72 0.10 0.50 0.8 

5 3, 7 0.92 0.60 0.19 0.47 0.8 

6 4, 7 0.76 0.78 0.32 0.47 0.8 

7 4, 7 0.76 0.90 0.41 0.47 0.8 

8 4, 7 0.92 1.00 0.41 0.47 0.8 

9 5, 7, 8 0.82 0.75 0.29 0.40 0.8 

10 5, 7, 8 0.58 0.60 0.10 0.40 0.8 

11 5, 7, 8 0.58 0.27 0.44 0.36 0.8 

12 5, 7, 8 0.58 0.21 0.75 0.32 0.8 

 

1) Wind Power Plant 
The generation capability between two consecutive hours 

depends on the changes of wind speed at the location where the 
wind-mill is constructed. However, the difference on wind 
speed between two consecutive hours is very small, at 1-2m/s 
(approximately 15%). 

2) Solar Power Plant 
As mentioned, two reasons which lead to the change of 

generation power between two consecutive hours of a solar 
power plant are the variation of solar radiation intensity during 
the day and the duration of sunny time per day. However, 
changes of solar radiation between two consecutive hours are 
still petite and accounted for around 15% as in the wind power 
case. Table XIV presents the limitation of generation power 
variation between two consecutive hours of different types of 
power plants which may be called as the load traceability of 
power generation. 

TABLE XIV.  LOAD TRACEABILITY RATIO OF POWER GENERATION (%) 

Hydro Coal Gas Biomass Wind PV 

10 20 60 20 15 15 

 



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F. CO2 Emissions and Prices 

1) CO2 Emission Factor 
The emission factors of CO2 for different energy sources in 

Vietnam are shown in Table XV. Emission factors of wind 
energy and solar energy are cited from [20, 21]. 

TABLE XV.  CO2 EMISSION FACTORS IN VIETNAM 

Unit Coal Gas Biomass Hydro PV Wind 

[g-CO2/kWh] 1,473 464 20 11 40 11.7 

 

2) CO2 Prices  
Although the Clean Development Mechanism (CDM) 

issued by Kyoto Protocol (1997) has not been extended since 
2012, international CO2 trading market is still operating. 
Selling prices of CO2 in the global market are chosen at 18, 20, 

and 25 US$/short t-CO2, for year 2020, 2025, and 2030, 
respectively. Those are the lowest prices according to [22]. 

G. Levelized Cost 

In Vietnam, renewable power plants will be offered a fixed 
selling tariff (Table XVI). Reference values relevant to 
investment, power factor, lifetime, fuel consumption per unit 
production, operation and maintenance cost, fuel price are 
included in Table XVII. They are categorized as levelized cost. 
The values are cited from [9]. 

TABLE XVI.  ELECTRICITY PRICES BUYED BY EVN 

Unit Biomass [23] Wind [24] PV [11] Import [9] 

[US$cent/kWh] 7.4 7.8 9.35 6.02 

 

TABLE XVII.  LEVELIZED COST OF CONVENTIONAL POWER PLANTS [9] 

Indicator Unit 
Gas Coal Hydro 

2020 2025 2030 2020 2025 2030 2020 2025 2030 

Investment US$/kW 1,224 1,660 1,660 1,400 1,850 1,850 1,500 1,500 1,500 

Energy consumption kcal/kWhe 2,457 1,870 1,870 2,098 1,720 1,720    

Lifetime yr 25 30 50 

Fixed O&M US$/kW.yr 24.5 28 28 42 43.5 43.5 5 5 5 

Variable O&M US$/MWhe 0.88 1.37 1.37 0.15 3 3 2 2 2 

Interest rate (WB-IDA SUF) % 3.8 

Fuel price – low US$/MBtu 4.88 5.46 5.69 1.6 1.7 1.9    

Fuel price – high US$/MBtu 9.16 10.9 11.6 3.6 3.8 4.0    

Heat value (LHV) 1000kcal/kg 9.8 8.5 8.5 6.5 6.5 6.5    

 

IV. RESULTS 

When the input parameters are inserted into LINDO 
software, optimal generation scenarios of installed capacity and 
power generation production based on different power sources 
for the years 2020, 2025, and 2030 are generated as final 
results. The following values are calculated: CO2 emission 
capacity, electricity selling prices in case of non-purchasing 
mitigated-CO2, and electricity selling prices with sharing by 
mitigated-CO2 trading.  

A. Installed Capacity 

Optimum installed capacity of power generation is 
presented in Figure 1.  

 

 
Fig. 1.  Optimum installed capacity 

Hydro installed capacity is around 18.1GW, 18.6GW, and 
21.2GW in 2020, 2025, and 2030 respectively reducing from 
32% to 16.8%. It reaches its upper limit of installation and does 
not change through the scenarios. Coal generation capacity on 
the other hand, is dramatically increased from around 15.8-
17GW in 2020 to 24.6-29.3GW in 2025, and 38.9-49.9GW in 
2030 changing its percentage of total capacity from about 
27.8% to 40.6%. Gas generation capacity is increased by years 
but not changed much through different scenarios at around 
9.5GW in 2020, 15.6GW in 2025, and 23.2GW in 2030. In 
percentage of total, it varies in the range of 16.6% to 20.3%. 
The other generations are all reaching their upper limit 
installation. All scenarios have reserved capacity at more than 
20% not including renewable sources. 

B. Power Generation Production 

Figure 2 illustrates the computed-results of optimum 
electricity generations. Hydro generation reaches its upper limit 
from 66.3 to 68.6TWh from 2020 to 2030 respectively 
decreasing its percentage from 35.8% to 13.9%. Coal 
generation increases dramatically to meet the increasing load 
demand. The generation takes a very high percentage from 
41.5% to 65.8%. Gas generation shares 19% to 26.3% of total, 
depending on the years and scenarios. Other generations are all 
reaching their upper limits. 

C. CO2 Emission Capacity 

CO2 emissions of the power generation system are shown in 
Figure 3. BAU scenario has the highest emissions of 188.9Mt-
CO2, 341.8Mt-CO2, and 516.9Mt-CO2 in 2020, 2025, and 2030 



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www.etasr.com Nguyen et al.: Green Scenarios for Power Generation in Vietnam by 2030 

 

respectively. Lowest emissions are resulted by the HG scenario 
and are reduced by 5.9% (2020), 20.4% (2025), and 28.4% 
(2030) compared to BAU. This is caused by a considerable 
increase of renewable sources, and very low load demand. 
Details of reduction in capacity of emissions are presented in 
Table XVIII. 

 

 

Fig. 2.  Optimum power generation production 

 

 

Fig. 3.  CO2 emissions 

TABLE XVIII.  CO2 REDUCTION COMPARED TO BAU 

Scenario 2020 2025 2030 

LG 11.14 62.04 127.74 

HG 11.14 69.60 146.92 

Crisis 6.05 30.80 2.38 
 

D. Generation Cost 

Generation costs for both two cases of non-selling CO2 
emissions and selling mitigated CO2 are shown in Figure 4. 
Two ranges of generation cost, 4.3-5.5 and 6.0-7.7 
US$cent/kWh have been reached in correspondence with low 
and high fuel price future scenarios. It is demonstrated that 
selling mitigated CO2 will help reduce the generation cost. 
Maximum reduced cost is recorded in HG scenario in 2030 at 
10% in case of non-selling mitigated CO2. Maximum amount 
of selling CO2 emission reduction is 2.64 billion US$ in HG 
scenario in 2030. This helps generation cost of both HG and 
Crisis scenarios to be nearly the same in 2030. Selling 
mitigated CO2 also makes generation cost of LG scenario in 
2030 lower than that of BAU. BAU scenario has the same cost 

for both cases of selling and non-selling mitigated CO2 as it has 
no emission reduction. 

 

 

Fig. 4.  Electricity generation cost 

V. CONCLUSION 

Four projection scenarios of power generation by 2030 in 
Vietnam have been proposed. Three variable key-factors have 
been selected for creating the power generation scenarios: 
future fuel price, reduction of load demand caused by the 
penetration of LED technology and rooftop PV systems, and 
the introduction of power generation from renewable sources. 
The scenarios named BAU, LG, HG, and Crisis are taken into 
account for finding the optimum structure of power generation 
system in terms of installed capacity and power generation 
production. CO2 emission reduction compared to BAU 
scenario and its effects on reducing generation cost are 
calculated with the aim to give an understanding of the 
magnitude of the impact of green scenarios on the power 
generation system.  

BAU is the worst scenario in terms of CO2 emissions 
because of the highest proportion of generation from coal and 
fossil fuels. It also leads to a poor energy security because 
thermal generations increase their generation share at about 
62.6%, 72.5%, and 75.1% of total in 2020, 2025, and 2030, 
respectively. LG and HG scenarios show their positive impacts 
on CO2 emissions and generation cost reduction. HG scenario 
is defined as the greenest one when renewable energy sources 
contribute 11.2% (2020), 15.5% (2025), and 19.4% (2030) of 
total generation. Maximum emission reduction is about 
146.92Mt-CO2 in HG scenario in 2030. Additionally, selling 
mitigated CO2 can make green scenarios more competitive to 
BAU and Crisis in terms of cost. Two ranges of generation cost 
(4.3-5.5 and 6.0-7.7US$cent/kWh) have been reached in 
correspondence with the low and high fuel price scenarios. 
These generation costs are low enough to support future 
sustainable economic development in Vietnam. Replacing 
conventional electric lamps with LED lamps and increasing the 
installed capacity of rooftop PVs may help reducing electric 
load demand. Increasing the contribution of renewable 
generation will make the HG scenario become more attractive 
both in environmental and economic aspects when the Crisis 
scenario comes. Generation costs of all scenarios shall become 



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cheap enough for promoting economic development in 
Vietnam to 2030. 

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