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Article

Analysis of Six Active Power Control Strategies of Interconnected Grids with VSC-HVDC

1
School of Electrical Engineering, Korea University, Anam-ro, Sungbuk-gu, Seoul 02841, Korea
2
Department of Electrical Engineering, Tongmyong University, Sinseon-ro, Nam-gu, Busan 48520, Korea
*
Author to whom correspondence should be addressed.
Appl. Sci. 2019, 9(1), 183; https://doi.org/10.3390/app9010183
Submission received: 29 November 2018 / Revised: 28 December 2018 / Accepted: 31 December 2018 / Published: 6 January 2019
(This article belongs to the Special Issue HVDC for Grid Services in Electric Power Systems)

Abstract

:
In this paper, the generator angle stability of several active power control schemes of a voltage-source converter (VSC)-based high-voltage DC (HVDC) is evaluated for two interconnected AC systems. Excluding frequency control, there has been no detailed analysis of interconnected grids depending upon the converter power control, so six different types of active power control of the VSC-HVDC are defined and analyzed in this paper. For each TSO (transmission system operator), the applicable schemes of two kinds of step control and four kinds of ramp-rate control with a droop characteristic are included in this research. Furthermore, in order to effectively evaluate the angle stability, the Generators-VSC Interaction Factor (GVIF) index is newly implemented to distinguish the participating generators (PGs) group which reacts to the converter power change. As a result, the transient stabilities of the two power systems are evaluated and the suitable active power control strategies are determined for two TSOs. Simulation studies are performed using the PSS®E program to analyze the power system transient stability and various active power control schemes of the VSC-HVDC. The results provide useful information indicating that the ramp-rate control shows a more stable characteristic than the step-control for interconnected grids; thus, a converter having a certain ramp-rate slope similar to that of the other generator shows more stable results in several cases.

1. Introduction

Presently, renewable energy resources are considered a best practice in the response to global warming, and these power resources are concentrated in remote areas in order to effectively generate power. However, several instability issues arising from uneven large power generation requires TSOs (transmission system operators) to complement the grid structure [1]. Moreover, based on References [2,3,4], grid interconnection is emerging as an effective alternative for solving stability problems. For example, Nordic power systems in which several grids are interconnected by AC or DC links have increasingly accepted renewable energy resources, and have updated their hourly power exchange clauses [5]. This additional effort has led to the mitigation of several instability issues caused by uneven power generation, and many research works have also reported that renewable energy resources have become more accepted in many other countries [6].
In order to interconnect two different power systems, there are two options for TSOs: AC or DC lines. Nowadays, grid interconnection using an AC transmission line has a problem that increases the system complexity from the operation point of view, and may adversely decrease the system reliability. In fact, large blackouts have clearly confirmed that the close coupling of the neighboring systems might also include the risk of uncontrolled cascading effects in large and heavily loaded systems [7]. Furthermore, the AC system is vulnerable to sub-sea transmission connections and long interconnection; thus, the DC system, which has the advantage of high controllability, has been widely deployed for grid interconnection projects [8]. Considering the grid strength as the SCR (short circuit ratio) at each point, it is well known that the LCC (line commutated converter)-based high-voltage DC (HVDC) is restricted in that the converter cannot work properly if the connected AC system is weak [9]. Conservatively, in the case of AC systems with an SCR lower than 1.5, synchronous condensers have to be installed so as to increase the SCR of the AC system. In addition, the reactive power should be compensated depending upon the power sent, which reduces the simplicity of controllability in LCCs. The voltage-source converter (VSC)-HVDC has similar stability issues; however, it offers significant advantages such as high controllability, reliability, and small size. Benefiting from the significant technical advances in insulated gate bipolar transistors (IGBT), the VSC has become a competitive alternative to the LCC, so the VSC-HVDC is more commonly deployed nowadays. In the VSC system, two main stability issues have generally been presented in detail to date:
(1) Operation region of the VSC-HVDC
The reactive power of the VSC-HVDC can be limited according to the AC grid voltage and the equivalent impedance. In addition, the DC voltage control and PLL (Phase-Locked Loop) can restrict the power angle to approximately 51° for a stable operation without the support of the dynamic reactive power [10]. In order to obtain an improved power transfer capability from the VSC-HVDC, the X/R ratio (the ratio of the system reactance to the system resistance) and the impedance angle must be considered. Therefore, the SCR index representing the grid strength is an important factor from the perspective of the capability region.
(2) Dynamic performance of the VSC-HVDC
In previous studies on the relationship between the PLL and the VSC-HVDC, many authors have mentioned that a converter with large PLL gains that is connected to a weak AC grid (2 < SCR) is prone to instabilities when subjected to a disturbance [11]. This is because the PLL that is used for the angle-reference generation can easily generate an unstable eigenvalue with high proportional gains. The AC voltage phase is highly sensitive to the d and q current injections of the converter in a weak grid. Detailed results have been described in a few references [12,13].
However, the stability issues mentioned above can be resolved by the robust compensator design mentioned by many authors [12,13,14,15]. The robust PI (Proportional and Integral) parameters, feedforward controllers, and adjusted PLL parameters enable the stable operation of VSC-HVDC, and the damping condition which occurs at a certain frequency range can be mitigated. Therefore, in this work, the VSC-HVDC system is deployed without considering the small signal stability issues, and the main contribution of this paper is to analyze the impact of six active power control strategies on the generator angle stability of two interconnected grids.
Excluding the contingency event, the fixed power control for two grids is commonly used to lessen the operation burdens of TSOs. However, during a contingency event, the power should be adjusted to provide grid services such as frequency support or transient stability support. According to the previous works related to VSC control for grid service, Reference [16] demonstrated the AC transmission emulation control strategy, which acts like an AC line when a contingency event occurs. It is able to mitigate the possible overloading of adjacent AC transmission, and maintain power balance between metropolitan regions. However, the transferred power is not exactly estimated since the output power is varied depending upon contingency event types; thus, it is not suitable for interconnected grids since there is a clear exchange clause in their agreement. In Reference [17], the flexible operation of the generator tripping scheme was achieved without a large decelerating energy as the generators trip, and it was confirmed that a simple converter control strategy that transfers the maximum power reserve instantly to the fault area surely contributes to the stability of the AC network. However, this paper only addressed one kind of step control. In References [18,19], the DC voltage droop, local frequency control, and weighted-average frequency control are compared in detail; however, this analysis was performed in an embedded MTDC (multi-terminal DC) environment. In References [20,21], the kinds of frequency–power modulation control strategies for the converter to enhance the system transient stability are introduced. As can be observed, there has been no detailed analysis of interconnected grids depending upon the several converter power control schemes in a point-to-point environment. Therefore, in this paper, two step control and four ramp-rate control scenarios are specifically defined, and then simulated to provide useful feasibility studies results for grid operators.
A dynamic control model of the VSC-HVDC is developed written by Fortran language in the PSS®E program (Power Transmission System Planning Software), and the ideal averaged equivalent VSC model is used. The MMC (modular multilevel converter) is not used since the AC system stability is the major observation target. To perform this analysis, the GVIF index, meaning the Generators-VSC Interaction Factor, is newly defined in Section 2. In Section 3, the introduction of the VSC-HVDC model serves to illustrate the configuration of the active power controller. In addition, six active power control strategies are defined in Section 4. Lastly, a simulation of the transient stability regarding the control schemes is performed.

2. Identify PGs (Participating Generators) with the GVIF Index

As shown in Figure 1, areas 1 and 2 are interconnected by a VSC-HVDC link. The initial DC power direction is from area 1 to area 2, so the converter is used to provide auxiliary service for area 2. This grid structure may be in the form of an interconnection link between countries or between regions [18]. If multiple generators are connected in parallel to each area, it is difficult to detect which generator contributes to incremental power according to the converter power change. The TSOs must determine which generators respond to the converter control, and this process is needed to distinguish the participating generators (PGs) group.
A traditional synchronous generator consists of a governor and a prime mover to support frequency regulation. The simplified first-order differential equation of the dynamic generator model is shown in Equations (1) and (2), where P v is the valve position of the governor; P r e f is the power reference of governor; R is the droop value; P m is the prime mover output power; and T G and T P are the time constants of the governor and prime mover, respectively [22].
d Δ P v d t = Δ P v T G + Δ P r e f T G 1 T G R Δ f .
d Δ P m d t = Δ P m T P + Δ P v T P .
Based on Equations (1) and (2), the generators react to grid frequency change as Δ f . If all generators have the same frequency droop value, an individual generator increases in the same MW power in a liner decrease in speed corresponding to the percent droop selected and no-load frequency. However, in the real grid operation, the frequency measurement result as Δ f is slightly different at each region at the same time; thus, the Δ P v and Δ P m were made unlike the expected values. During the dynamic state, the generator output power is mainly determined by the droop value as R, but it is also related to the distance to the point at which the frequency change occurs. As a result, the approximate incremental output of each generator with the droop slope can be estimated, but it is difficult to derive the exact incremental power from each generator. In order to consider both the governor droop value and the electrical distance between the generators and the converter, the new grouping index, referred to as the Generators-VSC Interaction Factor (GVIF) to select the PGs is implemented as follows.
G V I F i , j = Δ P i Δ P j .
where bus i is the generator bus connected in area 1. Bus j is the VSC-HVDC bus, and as we know, the multi-infeed HVDC system has several bus positions as j 2 . The GVIF is the dynamic active power change of bus j over the active power change of bus i. When the active power change Δ P j is 1%, the active power change ratio of bus i is the GVIF. If the generators have the same frequency–power droop value, the electrical distance is the main factor impacting the GVIF since the frequency measurement results are slightly different at each region. Thus, using the GVIF, the frequency measurement result errors could be corrected on each generator output. In the steady-state condition, since the frequency change point is always the converter bus as bus j, the generators with a high GVIF index could be considered to be closer to the converter or to have a high droop value. The generator which has a zero value of GVIF does not participate in the incremental power generation. In this paper, we define the generators with GVIF > 0 as PGs, and the angle stabilities of all PGs are evaluated by the general transient stability index as angle spread in Section 5.

3. Active Power Controller Design of VSC-HVDC

The schematic diagram of the VSC-HVDC is illustrated in Figure 2. The widely used vector controller is applied in the VSC. Let the converter side impedance be simply modeled as a series-connected three phase inductor and resistor, and the AC grid in the abc frame is:
[ v 1 d v 1 q ] [ v 2 d v 2 q ] = R [ i d i q ] + L d d t [ i d i q ] [ ω L i q ω L i d ] ,
where the v 2 is the voltage at PCC and v 1 is the voltage at the converter. In addition, R and L are the resistance and inductance, respectively, and i is the current flowing to the AC grid. Filter components prevent the generation of harmonic current by the converter, and they also affect the stability between the AC grid and the VSC.
The reference voltage generated by the inner current control loop is transformed back into the a b c frame and used for Pulse With Modulation (PWM) to produce the desired converter three-phase voltage. The voltage reference sent to the PWM is represented by:
[ Δ v 2 d Δ v 2 q ] = [ A d ( s ) A q ( s ) ] [ Δ i d , r e f Δ i d Δ i q , r e f Δ i q ] + ω L [ Δ i q Δ i d ] + [ v 1 d v 1 q ] ,
where A d ( s )   and   A q ( s ) = k p s + k i s .
The PWM switching delay is then approximated by a first-order Padé approximation as follows:
G P W M ( s ) = 1 1.5 T d s 2 1 + 1.5 T d s 2 ,
where T d is the switching delay in the PWM. Then, combining (5) and (6), the equation can be rearranged by the input terms as v 2 d q and i d q , r e f , with i d q as the output. The transfer functions of the inner controller are expressed by:
i d = A · v 2 d + B · i d , r e f ,
i q = A · v 2 q + B · i q , r e f ,
where A = 1 G P W M ( s ) ( R + L s ) + G P W M ( s ) · A d ( s ) , B = G P W M ( s ) · A ( s ) ( R + L s ) + G P W M ( s ) · A q ( s ) .
The q-axis current of the d-q frame is aligned with the AC system phasor based on the PLL, i.e., i q = 0 . Thus, the converter admittance is derived as i a b c / v 2 , which is obtained as follows:
Y V S C ( s ) = 1 G P W M ( s ) ( R + L s ) + G P W M ( s ) · A d ( s ) .
Depending on (9), the d-axis current flowing to the AC grid to control active power is represented in Figure 3. Following the block diagram, the stability between the AC grid and converter can be analyzed based on the initial operating point of the VSC. However, the detailed small signal analysis is not of interest in this paper, and the useful results were given with an impedance-based stability analysis theorem by References [23,24].
Following the d-axis current response of the converter, the active power of the PGs is simultaneously activated with their own GVIF index. The incremental power of the PGs of area 1 is transferred to area 2, and its characteristic is adjusted by several active power control strategies, as illustrated in the following section.

4. Analysis of Active Power Control Strategies

Excluding the frequency control, two major active power control strategies can be applied for the VSC-HVDC. The first one is the step control, which releases active power step-by-step at certain times, as shown in Figure 4a. The second one is the ramp-rate control, which transfers active power with a specific slope, as illustrated in Figure 4b. In this section, each control strategy is introduced and then defined.

4.1. Introduction of Step Control and Ramp-Rate Control Strategies

As is generally known, the step control sustains its initial power in normal stable operation, then increases power at certain times, when area 2 has a frequency drop or emergency event. By contrast, the ramp-rate control has a preset ramp-rate slope (RRS), as shown in Figure 5. The power changes from one stable state to another stable state with a ramping event, and considering a discrete time representation, the ramp-rate of P v s c at the kth instant can be determined using the following expression:
R R S = d P v s c d t ( k ) = [ P v s c ( k ) P v s c ( k 1 ) ] t ( k ) t ( k 1 ) .
The RRS can vary depending upon | Δ P v s c ( k ) | , which is the absolute value of the deviation between P v s c ( k 1 ) and the active power reference as P v s c r e f . If the | Δ P v s c ( k ) | is large, a high RRS is applied so as to ensure a fast response. On the other hand, if the power order as P v s c r e f is small, a low RRS is applied to follow the final P v s c r e f value. Such a droop characteristic is given in Equation (11) with Figure 5.
R R S ( k ) = { R R S m i n ,   i f   | Δ P v s c ( k ) | < Δ P m i n R R S m i n + D B R R S D B Δ P × [ | Δ P v s c ( k ) | Δ P m i n ] , i f   Δ P m i n | Δ P v s c ( k ) | Δ P m a x R R S m a x ,   i f   | Δ P v s c ( k ) | > Δ P m a x .
The RRS(k) is a droop-based desired ramp-rate; R R S m a x and R R S m i n are the max and min ramp-rate slopes of Δ P v s c , respectively; D B R R S is the difference between and R R S m a x and R R S m i n ; Δ P m i n and Δ P m a x are the lower and upper bands of dynamic change of active power variation; and D B Δ P is the difference between and Δ P m i n and Δ P m a x . As mentioned previously, if the converter receives a high P v s c r e f order by the TSO, the active power sharply increases with a ramp rate of R R S m a x , and a large active power is transferred from area 1 to area 2. Based on References [16,17], it was confirmed that converter power control is helpful when the power system has a contingency event; therefore, this control strategy largely contributes to the frequency stability of area 2. However, we can also expect that the angle stability of area 1 could be further worsened. On the other hand, if the converter reaches R R S m i n when the | Δ P v s c ( k ) | is smaller than Δ P m i n , a small amount of active power is delivered to area 2, and the angle stability of the PGs in area 1 will be more improved than that in the R R S m a x case.

4.2. More Detailed Description of Step Control and Ramp-Rate Control Strategies

There is an N-1 contingency event in area 2 with the given scenario, which is represented in Figure 6. Each country, if it has a different Special Protection System (SPS), as the generator tripping schemes are generally called, commonly commands the specific generators to be tripped so as to balance the network power. Basically, the nine cycles as time delay should be taken with the generator tripping scheme, since a mechanical switch is included. As the electronic power equipment only requires communication delay, the activating time is naturally fast [17]. In this paper, three cycles of communication delay are adopted for t 1 time, and the minimum frequency occurred at t 2 time, as shown in Figure 6 and Figure 7. Accordingly, various active power control strategies can be applicable to the VSC-HVDC to supply more power to area 2. Given the frequency fluctuation of area 2, six active power control strategies in total are introduced hereafter.
Figure 8a,b both show step control, with the only difference being a power release time. In (a), the power increased at t 1 , which is the minimum time to receive an SPS signal as 1.05 s. In (b), the converter changes its power at t 2 . Benefiting from the fast response of power electronics, (a) and (b) show advantages of being able to control the power step-by-step, unlike the common generator characteristics. Except for (a) and (b), all other control strategies are ramp-rate control strategies with different RRSs and sending times. Figure 8c,d have different RSSs between t 1 and t 2 , which are derived from two different power references. More specifically, the power command in (c) is twice the value of (d); thus, the RRS of (d) is selected to be half. This is to observe the results according to both initial power support speed and amount. Figure 8e,f discuss how the angle stability of each area changed during the recovery stage of area 2. Thus, the two control strategies have the same power reference value, but different RSSs between t 2 and t 3 . For this, the t 3 is selected for the control variable to adjust the RSS. In the simulation study, the t 3 of (e) is twice the value of (f), so that (e) has an RRS twice that of (f). According to the control characteristic, the six control schemes are defined in Table 1, and specific simulation results are introduced hereafter.

5. Transient Stability Simulation Results with Six Different Active Power Control Schemes

The interconnected grid configuration for simulation studies is represented in Figure 9, and the three-phase fault event at 345 kV AC transmission occurs in area 2. The detailed system parameters are defined in Table 2. The averaged equivalent circuit of the two-level VSC is used for this feasibility study, and it was supplemented by one on-state switch resistance in each phase, and an equivalent current source at the DC side. Note that the VSC model should be injected by current sources in the PSS®E program, and the outer and inner current controller parameters are adjusted to achieve the desired system response. Accordingly, the six different power output characteristics of the VSC-HVDC are simulated, as shown in Figure 10. There are two power control start times of t 1 and t 2 . (a), (c), and (d) supply power at t 1 , and (b), (e), and (f) control power at t 2 . The RRS and power reference values are all different according to each control characteristic.
As mentioned in Section 2, in order to select PGs when the converter controls its power, the GVIF index of the Korean power system is analyzed. The PGs are selected using Equation (3) with Δ P v s c = 100 MW, and the PGs list is given in Table 3. As a total of 269 generators are connected in the Korean grid at the peak load condition; however, for the sake of convenience, only 22 generators with GVIF are illustrated in this paper.
As can be observed in Table 3, the steam turbine (ST) has a zero value of GVIF, since it has a zero droop value, so the active power is not adjusted in response to the frequency variation. On the other hand, the gas turbine has a certain droop value that is more sensitively activated than the steam turbine during the dynamic converter power control. In order to correct the different frequency measurement results, the GVIF index is used to select PGs. We conclude that the power transmitted to area 2 comes from the generators with GVIF values larger than zero. In addition, as shown in Table 3, the most influential PGs are Yunghung #G3~#G6 with GVIF = 0.01. With the driven PGs list, the angle spread, which is the difference between the largest and smallest participating machine angles, is analyzed for interconnected areas.

5.1. Angle Spread Evaluation with PGs

In order to evaluate angle spread, the Overcorrections index, which is generally used for control response determination, is introduced in this paper. Assume that x i n i t i a l is the original steady state value of variable x, x F is the first encountered peak of x during a transient event, and x T is the second encountered peak of x during a transient event.
x 0 = | x i n i t i a l x F x i n i t i a l | + | x i n i t i a l x T x i n i t i a l |
x is defined in this paper as the angle spread. Thus, the larger x 0 is, the worse the angle stability of the PGs, and if x 0 is large enough, there is a possibility of loss of synchronisms. The locus of x 0 as well as the brief conclusions are well illustrated with each scheme hereafter.

5.1.1. Step Control

The results in Figure 11 show the angle spread of two interconnected grids with the control scheme as (a) and (b). Both control schemes are step control strategies, and we aimed to determine whether the active power should be transmitted at t 1 or t 2 . In area 1, the only difference between the two schemes is the power release time, so we may see only the result of area 2. From the angle spread results of area 2, it can be seen that sending power at t 2 can further improve the angle stability. More specifically, the first damping of angle spread as x F after the contingency event is mitigated at about 1.45 s, and the recovery characteristic is more improved from 2.1 s to 3 s. This is because the power from area 1 contributes to the frequency recovery characteristic of area 2. However, in (a), the power is transmitted immediately after the fault, so it contributes less to the angle stability of area 2. The reason for this is that the initial frequency drop driven by fault is momentarily increased due to the immediate active power support. Therefore, the PGs of area 2 generate a relatively small amount of power according to the small frequency drop. However, this process finally makes a slow frequency recovery, and the angle stability of the PGs becomes worse than that in (b). Therefore, we can conclude that sending power during the frequency recovery stage is more beneficial to both TSOs.

5.1.2. Ramp-Rate Control

Figure 12 shows the results regarding (c) and (d). Both control schemes are ramp-rate control strategies, and both the RRS between t 1 and t 2 and the active power reference are different. In (c), 1000 MW power is transferred to area 2 with a high RRS, so the angle stability of the sending side is further worsened compared to that in (d), which sends 750 MW. In area 1, (c) experiences a sudden large power change at t 1 , and shows a more unstable result. Concerning the receiving side in area 2, the angle deviation x 0 is explicitly different between the two methods. The results show that the generators of area 2 could not cover the severe frequency drop, and there is a possibility of loss of synchronisms at time = 1.45 s. Therefore, applying method (c) is more stable in terms of the angle stability of area 2. However, a tradeoff was observed as method (d) is more suitable for area 1, where the SCR is low.
Figure 13 shows the results regarding (e) and (f). Both control schemes are ramp-rate control strategies, and the only difference is the RRS between t 2 and t 3 . The power change references are all the same as 1000 MW; thus, the | Δ P v s c ( k ) | is also the same. By adjusting time t 3 , the two control methods were set to have a twofold slope difference. Scheme (f), which has a low RRS, shows slightly greater angle stability results in area 1. From the result of area 2, scheme (e) shows a greater angle stability result that the first encountered peak time and its recovery characteristic is faster than that in (f). Thus, it is concluded that active power control with a certain RRS is more suitable for both areas. However, using an overly low RRS will limit the stability improvement of area 2.
Figure 14 shows the results regarding (c) and (e). Both control schemes are ramp-rate control strategies with the same RRS, and the only difference is the power sending time. In (c), the power is transmitted immediately following the contingency event (= t 1 ) while the power is increased during the frequency recovery stage (= t 2 ) in (e). As shown in the result of area 2, if the grid operator uses both ramp-rate control schemes, sending power during the frequency recovery stage shows more stable results in terms of the angle stability. This is because, as mentioned earlier in Section 5.1.1, the initial frequency drop will not be immediately reduced by (c). This characteristic causes the PGs of area 2 to generate less power. Therefore, at about 1.3 s the first damping angle x F is more mitigated with (e); thus, sending power at t 2 is more suitable for both TSOs.

5.1.3. Step Control vs. Ramp-Rate Control

The results in Figure 15 and Figure 16 are about (a) and (e), and (b) and (e), respectively. The main purpose of this simulation is to compare the step control and ramp-rate control strategies; thus, this comparison is the main result of this paper. The results explicitly show that the angle stability with the step control is more unstable in both areas. Using scheme (e) has more smaller value of x 0 than (a) as shown in Table 4. As a result, the VSC-HVDC connecting two different grids should have its own RRS considering both the sending and receiving side generator stability. Thus, it is recommended that the two TSOs should include the ramp-rate control clauses in the HVDC design phase when the interconnected mutual agreement is introduced.

5.2. Detailed Comparison of Six Power Control Strategies

The suitable control strategy was recommended for each TSO as shown in Table 5. It is confirmed that sending the active power at time t 2 is more effective than that at t 1 . This is because the reserve power is helpful during the frequency recovery stage. Furthermore, the ramp-rate control is more suitable than the step control to both areas since the sudden large power change causes the large angle variation of PGs. In addition, the mismatch of active power could further worsen the angle stability, so if the required active power is not estimated, the converter should have its own RRS which is not too far from the generators’ output characteristic. Furthermore, if the N-1 or N-2 contingency event occurs at the sending side while the power is transmitted to the receiving side, the ramp-rate control will show a more stable result at the sending side grid. At last, the TSOs should consider the SCR of two grids based on the driven results, and select the appropriate scheme as shown in Table 5. This information will be useful for two TSOs planning grid interconnection projects.

6. Conclusions

To date, the frequency control for interconnected grids has been analyzed in several works. However, using frequency control increases the operation burden of one side. Thus, the impact of various types of active power control scheme should be simulated and analyzed. Furthermore, if there is a power increase clause between interconnected grids, this issue will be more critical for grid operators. In this paper, when the receiving side has an emergency event, six applicable active power control strategies are defined and simulated.
Before the simulation, our researchers expected that the step control, which is a powerful strength of power electronics, could further improve the angle stability of PGs due to its fast response. Contrary to expectations, the results show that the VSC-HVDC with certain RRSs similar to the other generator output characteristics provides more stable results in several cases. Our findings also confirm that sending power during the frequency recovery stage is more effective for the receiving side, whereas sending power right after the fault degrades the generator output characteristic since the low initial frequency error is measured at the generator side. To prevent this problem, one solution can be applied. If the droop slope of the generator is adjusted when the converter starts the power control, the small initial frequency error caused by the converter support can be corrected at each governor. This increases the generators output, and thus the frequency can reach the nominal value.
Furthermore, grid operators have to alter their control strategy based on the SCR of each grid base, as shown in Table 5. These results provide useful information to grid operators, and the advantages and disadvantages of each control scheme are well shown.

Author Contributions

The main idea was proposed by S.S. and G.J.; the experiment results were collected and analyzed by S.S. and M.Y.

Funding

This research received no external funding.

Acknowledgments

This work was supported under the framework of international cooperation program managed by National Research Foundation of Korea (No. 2017K1A4A3013579) and also supported by “Human Resources Program in Energy Technology” of the Korea Institute of Energy Technology Evaluation and Planning (KETEP), granted financial resource from the Ministry of Trade, Industry and Energy, Korea. (No. 20174030201540).

Conflicts of Interest

The authors declare no conflict of interest.

Nomenclature

θ Angle difference between E ˙ 1 and E ˙ 2
E ˙ 1 Internal generators voltage
E ˙ 2 Infinite bus voltage
w Rotor speed
H Shaft inertia
P i Mechanical power
P n Electrical power
v 1 voltage at voltage source converter
v 2 voltage at PCC
R Resistance between AC grid and converter
L Inductance between AC grid and converter
i Ac current from converter to AC grid
k p , k i PI controller in current controller of VSC
T d Switching delay in PWM
R R S Ramp-rate slope of VSC
| Δ P v s c ( k ) | Absolute value of the deviation between P v s c ( k 1 ) and active power reference as P v s c r e f
x 0 Overcorrections for the evaluation of angle spread

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Figure 1. Two interconnected grids with a voltage-source converter (VSC)-based high-voltage DC (HVDC).
Figure 1. Two interconnected grids with a voltage-source converter (VSC)-based high-voltage DC (HVDC).
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Figure 2. VSC control block diagram. PWM: Pulse With Modulation; PLL Phase-Locked Loop.
Figure 2. VSC control block diagram. PWM: Pulse With Modulation; PLL Phase-Locked Loop.
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Figure 3. D-axis current control structure of the VSC; PI: Proportional and Integral.
Figure 3. D-axis current control structure of the VSC; PI: Proportional and Integral.
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Figure 4. Two major active power control schemes: (a) step control (b) ramp-rate control with different ramp-rate slopes (RRSs).
Figure 4. Two major active power control schemes: (a) step control (b) ramp-rate control with different ramp-rate slopes (RRSs).
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Figure 5. Different RRSs of ramp-rate control; DB: difference between.
Figure 5. Different RRSs of ramp-rate control; DB: difference between.
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Figure 6. Contingency scenario in area 2.
Figure 6. Contingency scenario in area 2.
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Figure 7. Frequency drop during a contingency event in area 2.
Figure 7. Frequency drop during a contingency event in area 2.
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Figure 8. Six active power control schemes: (a) step control at t 1 ; (b) step control at t 2 ; (c) ramp-rate control with high RRS between t 1 and t 2 ; (d) ramp-rate control with low RRS between t 1 and t 2 ; (e) ramp-rate control with high RRS between t 2 and t 3 ; (f) ramp-rate control with low RRS between t 2 and t 3 .
Figure 8. Six active power control schemes: (a) step control at t 1 ; (b) step control at t 2 ; (c) ramp-rate control with high RRS between t 1 and t 2 ; (d) ramp-rate control with low RRS between t 1 and t 2 ; (e) ramp-rate control with high RRS between t 2 and t 3 ; (f) ramp-rate control with low RRS between t 2 and t 3 .
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Figure 9. System configuration for simulation studies.
Figure 9. System configuration for simulation studies.
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Figure 10. Six power control schemes of the VSC-HVDC.
Figure 10. Six power control schemes of the VSC-HVDC.
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Figure 11. Angle spread results of each area according to (a) and (b) in Table 1.
Figure 11. Angle spread results of each area according to (a) and (b) in Table 1.
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Figure 12. Angle spread results of each area according to (c) and (d) in Table 1.
Figure 12. Angle spread results of each area according to (c) and (d) in Table 1.
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Figure 13. Angle spread results of each area according to (e) and (f) in Table 1.
Figure 13. Angle spread results of each area according to (e) and (f) in Table 1.
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Figure 14. Angle spread results of each area according to (c) and (e) in Table 1.
Figure 14. Angle spread results of each area according to (c) and (e) in Table 1.
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Figure 15. Angle spread results of each area according to (b) and (e).
Figure 15. Angle spread results of each area according to (b) and (e).
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Figure 16. Angle spread results of each area according to (a) and (e).
Figure 16. Angle spread results of each area according to (a) and (e).
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Table 1. Six different active power control strategies.
Table 1. Six different active power control strategies.
DenominationControl TypeRRSControl Time
(a)Step- t 1
(b)Step- t 2
(c)Ramp-rate R R S m a x t 1 to t 2
(d)Ramp-rate R R S m i n t 1 to t 2
(e)Ramp-rate R R S m a x t 2 to t 3
(f)Ramp-rate R R S m i n t 2 to t 3
Table 2. System parameters.
Table 2. System parameters.
Grid ParametersValueConverter ParametersValue
Grid frequency60 HzVSC HVDC
Rated capacity
1200 MVA
Total load94,463 MWVSC HVDC
DC link voltage
250 kV
Total generation95,802 MWDC capacitance1500 μF
AC voltage of each side345 kV k p 1 , k p 3 0.5
Short circuit ratio25 k p 2 0.65
Leakage reactance0.07 pu k p 4 0.8
Transformer
Voltage ratio
345/250
250/345
k i 1 , k i 3 , k i 4 0.01
Transformer rating1200 MVA k i 2 0.1
Table 3. Generators-VSC Interaction Factor (GVIF) analysis of participating generators (PGs) in area 1 ( Δ P v s c = 100   MW ).
Table 3. Generators-VSC Interaction Factor (GVIF) analysis of participating generators (PGs) in area 1 ( Δ P v s c = 100   MW ).
Generator NumberGenerator ListInitial Power (MW)GVIFPGs
(O: PG, X: Not PG)
1Yunghung #G18000.007O
2Yunghung #G28000.007O
3Yunghung #G38700.01O
4Yunghung #G48700.01O
5Yunghung #G58700.01O
6Yunghung #G68700.01O
7Sininchen #G9167.70.004O
8Sinin #GT10167.70.004O
9Sinin #GT11168.340.003O
10Sinin #GT12168.340.003O
11Sininchen #S9181.260X
12Inchen #GT1164.0650.004O
13Inchen #GT3180.690.003O
14Inchen #GT51680.005O
15Inchen #ST1163.020X
16Inchen #ST2178.120X
17Inchen #ST3167.10X
18POS5 #GT1210.520.005O
19POS5#GT2210.520.005O
20POS6 #GT3217.170.005O
21POS6 #GT4224.40.005O
22POS6 #ST2232.650X
23
Table 4. Overcorrection results of (a) and (e) in area 2.
Table 4. Overcorrection results of (a) and (e) in area 2.
Target SystemControl
Strategy
x i n i t i a l x F x T x 0
area 2(a)93.04102.4288.60.147
(e)96.2190.820.05
Table 5. Suitable control scheme for each TSO (O: Most suitable/Δ: Suitable/X: Not suitable). SCR: short circuit ratio.
Table 5. Suitable control scheme for each TSO (O: Most suitable/Δ: Suitable/X: Not suitable). SCR: short circuit ratio.
Target System(a)(b)(c)(d)(e)(f)
Receiving side with high SCRΔΔOOOO
Receiving side with Low SCRXXOΔOΔ
Sending side with high SCRΔΔOOOO
Sending side with Low SCRXXΔOOO

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Song, S.; Yoon, M.; Jang, G. Analysis of Six Active Power Control Strategies of Interconnected Grids with VSC-HVDC. Appl. Sci. 2019, 9, 183. https://doi.org/10.3390/app9010183

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Song S, Yoon M, Jang G. Analysis of Six Active Power Control Strategies of Interconnected Grids with VSC-HVDC. Applied Sciences. 2019; 9(1):183. https://doi.org/10.3390/app9010183

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Song, Sungyoon, Minhan Yoon, and Gilsoo Jang. 2019. "Analysis of Six Active Power Control Strategies of Interconnected Grids with VSC-HVDC" Applied Sciences 9, no. 1: 183. https://doi.org/10.3390/app9010183

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