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Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8760-8764 8760 
 

www.etasr.com Hameurlaine et al.: Design of Protection Strategies and Performance Analysis of an HVDC Link … 

 

Design of Protection Strategies and Performance 
Analysis of an HVDC Link During Multiple 

Disturbances 
 

Abdelhadi Hameurlaine 
Department of Electrical Engineering  

University of Djelfa 
Djelfa, Algeria 

elhadi06@gmail.com 

Haouari Sayah 
Intelligent Control and Electrical Power System Laboratory 

University of Sidi Bel-Abbes 
Sidi Bel-Abbes, Algeria 
housayah@yahoo.fr  

Larbi Boukezzi 
Materials Science and Informatics Laboratory (MSIL) 

University of Djelfa 
Djelfa, Algeria 

larbiboukezzi@gmail.com 
 

Received: 20 April 2022 | Revised: 9 May 2022 | Accepted: 13 May 2022 

 

Abstract- In High Voltage Direct Current (HVDC) transmission 
system applications, the control and protection system plays an 

essential role in the overall performance. This paper aims to give 

solutions to some performance problems that can occur in the 

HVDC link. In this paper, ways to mitigate this serious 

malfunction of the commutation failure process in the operation 

of HVDC converters are studied and protection functions like the 

Commutation Failure Prevention (CFPREV) have been used. 

Furthermore, HVDC transmission systems are vulnerable to DC 

faults and its protection becomes ever more important with the 

fast growth in the number of installations. In this context, the DC 

fault protection function is one of the most important challenges 
to the development of HVDC transmission systems. The 

dynamics of the studied power system including the HVDC link 

are thoroughly investigated in this paper through various 
simulation scenarios. 

Keywords-commutation failure; control strategies; protection 

functions; HVDC; faults; performance 

I. INTRODUCTION  

High Voltage Direct Current (HVDC) transmission systems 
are an excellent asset in modern power systems, mainly for 
their ability to overcome problems of AC transmission, such as 
the interconnection of asynchronous grids, stability of long 
transmission lines, and use of long cables for power 
transmission [1-4]. Due to environmental, technical, and 
economical reasons [2-6], the HVDC system is a mature 
technology but it has certain constraints such as the risk of 
commutation failures [3]. Commutation failures following AC 
system disturbances may occur in HVDC systems, especially in 
the inverter station. This fault is the result of the failure to 
complete commutation before the commutation voltage 

reverses its polarity [5]. Furthermore, faults in the DC 
transmission system, which are generally pole-to-ground faults, 
block power transfer and are not likely to be of much 
significance unless voltage reduction occurs [7]. 

The objective of the current paper is to demonstrate ways to 
to improve HVDC system performance, especially during large 
disturbances, such as three-phase faults on the AC side of the 
inverter and DC line faults at the rectifier side. Therefore, in 
this paper, the DC fault protection (DCPROT) is inserted to 
detect faults on the line and take the necessary actions to clear 
them [8]. The protective function Commutation Failure 
Prevention (CFPREV) is used in the inverter [9]. The control 
subsystem mitigates commutation failures due to AC voltage 
dips. Finally, in order to improve the dynamic performance of 
the proposed controller and protection devices, various 
simulation scenarios are tested. The main conclusion is that the 
reliability of an HVDC link depends on control and on the 
protection system. 

II. SYSTEM MODELING AND CONTROL 

In order to define the needs in terms of control and 
protection, the first step is to develop a model for the HVDC 
transmission system. HVDC systems traditionally use the 
fixed-parameter PI controller to control the DC line current and 
excitation angle [10], where the rectifier station controls the 
DC current through the firing angle (α) and the inverter 
controls voltage through the extinction angle (γ). In general, a 
typical basic monopolar HVDC system can be configured as 
shown in Figure 1 [11], where the schematic diagram and the 
equivalent circuit are shown in (a) and (b) respectively [12]. 

 

Corresponding author: HameurlaineAbdelhadi 



Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8760-8764 8761 
 

www.etasr.com Hameurlaine et al.: Design of Protection Strategies and Performance Analysis of an HVDC Link … 

 

(a) 

 

(b) 

 

Fig. 1.  HVDC transmission link: (a) schematic diagram, (b) 
equivalent circuit. 

The direct current can be expressed using the equivalent 
circuits as [13]: 

cos cos0 0V Vd r d i
I
d

R R Rcr ciL

α γ−
=

+ −
    (1) 

where Rcr and Rci are the equivalent commutating resistances 
for rectifier and inverter respectively, and RL is the line 
resistance. Both impedances are nonlinear and are not pure 
resistive, referred from converter side AC systems. 

3
R Lcr cω

π
=

 
and L L Lcr co c= =     

(2) 

where Vd0r and Vd0i are the ideal no-load rectifier and inverter 
voltages respectively, referred from converter side AC systems. 

Therefore, the direct voltage Vd at any point on the line and 
the direct current Id can be controlled by controlling the internal 
terminal voltages: Vd0r cosa and Vd0i cosγ. These two voltages 
can be controlled by controlling the firing instant of the 
thyristor or through the tap changing of the converter 
transformer. Another important control function is 
implemented to change the reference current according to the 
value of the DC voltage. This control, named Voltage 
Dependent Current Order Limiter (VDCOL) [9], automatically 
reduces the reference current set point when DC voltage 
decreases during a DC line fault or a severe AC fault. Reducing 
the reference currents also reduces the reactive power demand 
on the AC system, helping to recover from fault. 

III. CONCEPTS OF THE PROPOSED PROTECTION 

In this section, we insert two different protection devices 
associated with the proposed control strategy to improve the 
dynamic performance of an HVDC system. The first one, at the 
rectifier, is the DC fault protection (DCPROT) to detect and 
remove faults in the DC line. The second protection function is 
the commutation failure prevention (CFPREV) at the inverter, 
which controls subsystem commutation failures due to AC 
voltage dips. In this context, the expected behavior in steady 
state and stability problems are discussed in order to define the 

needs in terms of control and protection. Moreover, the 
reliability of the HVDC control system depends on the 
regulators, but also on the protection sub-functions [14]. The 
actions that are taken by device protection systems when faults 
or dysfunctions occur are shown. To evaluate the performance 
of the proposed protection, simulation results are presented. 

A. DC Protection Function 

The protection is active in the rectifier. It will detect a fault 
on the DC side and will force the delay angle into the inverter 
region in order to extinguish the fault current [15]. The fault 
detection on the DC line is based on the drop in the line to 
ground voltage. The normal voltage polarity of the line is a 
parameter as well as the reference level of the fault detection. 
Delay time is used in the detection to discriminate between a 
line fault and other disturbances resulting in low DC voltage. A 
delay time of 200ms is allowed, after the DC system start-up, 
before activating the detection logic to make sure that the 
normal operating DC voltage is established. Also, an external 
signal generated by another protective detection will trigger a 
forced alpha during an adjustable interval sufficient to allow 
the deionization of the fault path prior to the re-application of 
voltage. 

B. Commutation Failure Prevention Function 

The objective of this device is to develop a control and 
protection strategy to accommodate large disturbances when an 
HVDC system is connected to a weak AC system [16]. This 
phenomenon is the result of the failure to complete 
commutation before the commutation voltage reverses its 
polarity, taking into account the need for sufficient extinction 
time for de-ionization and to re-establish the blocking ability. 
The protective function, used in the inverter, mitigates 
commutation failures due to AC voltage dips. After fault 
detection (three-phase or one-phase) an angle value is sent to 
the converter control in order to be deducted from the 
maximum delay angle limit. Commutation failure is the most 
common disoperation of an inverter due to the minimum limit 
on extinction angle gamma [17]. This puts a limit to the 
maximum firing angle for a successful inverter operation, as 
shown by the following equation: 

0180 ( )α β γ= − +    (3) 

A signal transmitted to the VDCOL indicates the detection 
of a commutation failure, as this VDCOL function prevents the 
detection of commutation failure by the CFPREV module, the 
VDCOL transiently reduces the current in order to prevent the 
converter from excessive current [18]. To detect three-phase 
faults abc-αβ transformation is used where, Uα and Uβ may be 
expressed by: 

1
(2 )
3

3
( )

3

U U U Ua cb

U U Ucb

α

β

= − −

= −







    (4) 

The CLARK transformation [19] is used for three-phase 
fault detection and zero-sequence voltage evaluation. The 



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www.etasr.com Hameurlaine et al.: Design of Protection Strategies and Performance Analysis of an HVDC Link … 

 

detection is based on instantaneous values, which ensure fast 
reaction of the control system when an AC fault occurs. 

IV. SYSTEM STUDY 

The HVDC system simulated in this study, is modeled 
based on the CIGRE HVDC benchmark system [20], as shown 
in Figure 2. The system is monopolar with a 12-pulse 
converter. The rectifier is connected to the strong AC system 
with a Short Circuit Ratio (SCR) of 5. The inverter is 
connected to the weak AC system with a SCR of 2.5. 

 

 
Fig. 2.  Basic configuration of the HVDC transmission system. 

The model description follows [20]. 

The AC side of the HVDC system consists of a supply 
network, filters, and converter transformers. The AC supply 
network is modeled by a Thevenin equivalent with equivalent 
source impedance [22]. The filters are added to absorb the 
harmonics generated by the converter and to supply the 
reactive power needed by the converter. The DC side of each 
converter consists of a smoothing reactor. The DC transmission 
line connected to each converter station is represented by a T 
network. The 12-pulse converter station is configured by two 
universal bridge blocks in series. The universal bridge block 
implements a universal three-phase power converter that 
consists of up to six power switches connected in a bridge 
configuration[23]. The system parameters of the HVDC system 
are given in Table I. 

TABLE I. HVDC SYSTEM PARAMETERS  

Parameter 
Value 

AC side 1 AC side 2 DC side 

AC voltage 500 kV 345 kV ----- 
Reactive Power 5000 MVA 10000 MVA ----- 

Frequency 60Hz 50Hz ----- 
DC voltage ----- ----- 500 kV 
DC current ----- ----- 2 kA 

Active power ----- ----- 1000 MW 
DC cable length ----- ----- 300 km 

Smoothing reactors ----- ----- 0.5 H 
 

V. SIMULATION RESULTS AND ANALYSIS 

In this section the behavior of the HVDC transmission 
system is analyzed. In order to test the controllers and the 
proposed protection functions, two different scenarios will be 
simulated in order to analyze the dynamic performance. During 

the first scenario, a DC line fault on the rectifier side is applied 
to observe the DC fault protection action. In the second one, a 
three-phase-to-ground fault on the AC side of the inverter is 
studied to evaluate CFPREV control. In both scenarios, the 
waveforms for electrical quantities like DC voltage, DC 
current, and firing delay angle α are presented and analyzed 
during the application of faults, at rectifier and inverter side, 
and finally, the corresponding inverter side AC voltage and AC 
current waveforms are shown. 

A. First Scenario:DC System Faults 

The scenario is shown in Figure 3. This fault is applied at 
 t= 0.7s for a duration of 50ms. The DC current increases 
quickly until 2.22p.u., and it is cancelled at the inverter side.  

 

(a) 

 

(b) 

 

(c) 

 

Fig. 3.  DC fault on the rectifier side. 

The DC voltage falls to zero at the rectifier. This DC 
voltage drop is seen by the VDCOL through DC fault 
protection. The VDCOL reduces the reference current to 

0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 1.4

-0.4

-0.2

0

0.2

0.4

0.6

0.8

1

1.2

1.4

Time (s)

V
d
 (

p
u
)

0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 1.4
-0.5

0

0.5

1

1.5

2

2.5

Time (s)

Id
 &
 I
d
re
f 
(p
u
)

Id
 &
 I
d
re
f 
(p
u
)

Id
 &
 I
d
re
f 
(p
u
)

Id
 &
 I
d
re
f 
(p
u
)

 

 

Id

Idref

0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 1.4
0

50

100

150

200

Time(s)

a
lp

h
a
(d

e
g
)

166 deg



Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8760-8764 8763 
 

www.etasr.com Hameurlaine et al.: Design of Protection Strategies and Performance Analysis of an HVDC Link … 

 

0.28p.u. at the rectifier. A DC current still continues circulating 
in the fault. At t=0.78s, the rectifier firing angle α is forced to 
be 166º by the DC protection function after detecting a low DC 
voltage. In this situation the rectifier operates in inverter mode. 
The DC line voltage becomes negative and the energy stored in 
the line is returned to the AC system. Then α is released at 
t=0.83s and the DC voltage and the current recover in 
approximately 0.5s. 

B. Second Scenario: AC System Faults 

Three-phase-to-ground fault is applied at the AC side of the 
inverter at t=0.7s and is cleared at t=0.75s. Figure 4 shows the 
inverter side, the DC voltage, DC current and firing delay angle 
during the fault. The oscillation of the DC voltage and current 
waveform are primarily caused by the controller action. 

 

(a) 

 

(b) 

 

(c) 

 

Fig. 4.  Three-phase-to-ground AC fault on the inverter side. 

The DC voltage at the inverter drops and the DC current 
increases rapidly to 2.22p.u. on the inverter side. When the 

fault is cleared at t=0.8s, the control function (VDCOL) 
operates and reduces the reference current to 0.3p.u.. The 
system recovers in approximately 0.35s after fault clearing. 
During the fault period, the DC voltage oscillates around zero 
due to the commutation failure on the inverter side. The control 
scheme provides smoother operation of the converter firing 
angles, which is shown in waveform firing angle. 

Furthermore, Figure 5(a)-(b) shows the phase AC voltage 
and AC current waveforms at the inverter side, for a three-
phase-to-ground fault. The AC fault does not affect the rectifier 
side AC system because the rectifier is connected to a strong 
AC system. The AC voltage becomes nearly zero, after the 
fault is cleared, the inverter side AC voltage increased to 
1.53p.u.. The AC currents at the inverter shows minor 
disturbance and high amplitude fault current flows with 
oscillations. 

 

(a) 

 

(b) 

 

Fig. 5.  Voltage and current responses under three phase to ground fault at 
the inverter. 

VI. CONCLUSIONS 

This paper focuses mainly on the HVDC performance 
assessment dynamic state under various scenarios. First, the 
dynamic response of the HVDC system is analyzed under 
unbalanced grid conditions. In a typical HVDC link, the 
rectifier station controls the DC current through the firing angle 
and the inverter station controls voltage through the extinction 
angle. The faults associated with an HVDC system are cleared 
through the action of protection devices. The protection devices 
thus play a vital role in the satisfactory operation of the HVDC 
systems. Simulation results show clearly that the reliability of 
an HVDC control system does not depend only on the 

0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 1.4
-1.5

-1

-0.5

0

0.5

1

1.5

Time (s)

V
d
 &

 V
d
r
e
f 

(p
u

)

 

 

Vd

Vdref

0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 1.4
-0.5

0

0.5

1

1.5

2

2.5

Time (s)

Id
 &

 I
d
r
e
f 

(p
u
)

 

 

Id

Idref

0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 1.4
110

115

120

125

130

135

140

145

150

155

Time (s)

a
lp

h
a
 (

d
e
g
)

0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 1.4
-2

-1.5

-1

-0.5

0

0.5

1

1.5

Time (s)

V
a
b
c
 (
p
u
)

 -1.53pu

1.23pu

0.6 0.7 0.8 0.9 1 1.1 1.2 1.3 1.4
-20

-15

-10

-5

0

5

10

15

20

Time (s)

I
a
b
c
 (
p
u
 /
1
0
0
M

V
A

)



Engineering, Technology & Applied Science Research Vol. 12, No. 3, 2022, 8760-8764 8764 
 

www.etasr.com Hameurlaine et al.: Design of Protection Strategies and Performance Analysis of an HVDC Link … 

 

controller, but also on protection functions. In this paper, the 
actions that are taken by some HVDC link protection systems 
when faults or dysfunctions occur are presented. The obtained 
results demonstrate that the DC fault line is eliminated by the 
rectifier operation in inverter mode through the increase of its 
firing angle to ensure the extinction of the residual current. 
This necessary action, is ensured by the DC protection device. 
For three-phase faults, the commutation failure prevention 
greatly reduces the risk of repeated commutation failures. 
Finally, from the simulation results, it can be seen that the 
system works stably with the purposed protection devices and 
the fixed parameter PI controller applied to an HVDC system. 
The protection devices implemented in this paper showed good 
performance under various scenarios. However, more extensive 
studies can be conducted in the future. Future work should 
explore other possibilities and routes in which this paper could 
lead to. The main perspectives should include: 

• The development of a Voltage Source Converter (VSC), 
with the insertion of these protection devices applied to the 
conventional HVDC link. 

• Protection and implementation of nonlinear control 
algorithms for VSC-HVDC systems. 

APPENDIX 

ABBREVIATIONS 

AC Alternating Current 
DC Direct Current 
DCPROT Direct Current Fault Protection 
CFPREV Commutation Failure Prevention 
HVDC High Voltage Direct Current 
VDCOL Voltage Dependent Current Order Limiter 

 

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