Abstract
Multi-terminal high-voltage DC (MTDC) technology is a promising way to transmit large amounts of offshore wind power to the main grids. This paper proposes a hybrid MTDC scheme to integrate several offshore wind farms into the onshore power grids at different locations. A hybrid four-terminal HVDC system comprising two onshore line commutated converters (LCCs) and two voltage source converters (VSCs) connecting an offshore wind farm is constructed in PSCAD/EMTDC. A coordination control scheme based on the VSCs’ AC voltage control and the LCCs’ DC voltage droop control is designed to ensure smooth system operation and proper power sharing between onshore AC grids. The operational characteristics of the system are analyzed. In addition, a black start-up method without any auxiliary power supply for the VSCs is proposed. The transmission scheme is tested through simulations under various conditions, including start-up, wind speed variation, and the disconnection of one VSC or of one LCC.
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1 Introduction
Electricity generation from wind power has been increasing rapidly around the globe in recent years, and offshore wind farms promise to become a very important part of wind energy generation. For example, by 2020, the target of the European Wind Energy Association (EWEA) is to have developed 230 GW of wind power within the European Union with 40 GW coming from offshore wind power plants [1].
In addition to the technical issues concerning the construction of offshore platforms, the method of transmitting efficiently large-scale offshore wind power to onshore power grids is a vital subject. It has been proven that, compared with high-voltage AC (HVAC) transmission, high-voltage DC (HVDC) transmission offers greater technical, economic, and environmental advantages for the integration of large wind farms across long distances [2, 3].
HVDC technologies, based on line commutated converters (LCC) [4, 5] or voltage source converters (VSC) [6, 7], have been studied for offshore wind farm integration. Compared with LCC transmission, the VSC scheme is more attractive in terms of independent active/reactive power control, no need for an external voltage source, and fast system control [2].
Several offshore wind power plants might be constructed over a vast sea area, such as those planned in the North Sea by EWEA [8]. To transmit that wind power, the multi-terminal HVDC (MTDC) system with an offshore DC grid could provide better economic and technical benefits than several two-terminal HVDC systems. VSC–MTDC technology for offshore wind power transmission has been studied and it has shown satisfactory performance [9, 10]. However, the limited capacity, high expense, and high power loss of VSCs currently constrain their commercial application.
From a techno-economic point of view, a hybrid MTDC system could be developed, in which multiple offshore VSCs connect wind farms for better control performance and fewer onshore LCCs connect to the AC power grids reducing expense and losses. Such a hybrid MTDC system was proposed in [11]; however, the study was just preliminary for a three-terminal system under normal conditions. In [12], a two-terminal hybrid HVDC system was developed and a direct power controller was designed for the VSC. A five-terminal hybrid HVDC system with a small proportion of injected wind power was investigated in [13].
The objective of this paper is to investigate the control scheme for a hybrid MTDC system integrating offshore wind farms and distributing wind power, and to analyze the operational characteristics of the system. The paper is organized as follows. Section 2 outlines a typical hybrid four-terminal HVDC system and its models. Section 3 investigates the coordination control strategies to ensure satisfactory system operation and power sharing between the onshore grids. Section 4 presents simulation results for the system validating the proposed scheme and strategies. Finally, the conclusions are outlined in Sect. 5.
2 System layout
It is anticipated that the proposed hybrid MTDC scheme could have different configurations with various numbers of converters. For simplicity, a typical bipolar four-terminal hybrid HVDC system with rated DC voltage of ±400 kV is proposed.
Figure 1 shows the single line schematic configuration of the system. WF1 and WF2 represent two doubly fed induction generator (DFIG)-based offshore wind farms in different energy areas. Two wind-farm-side VSCs (represented as WFVSC1 and WFVSC2) connect the respective wind farms and then intersect on the DC side through two short cables (1 and 2). The aggregated wind power is transmitted through a 100 km cable (5). On land, two grid-side LCCs (represented as GSLCC1 and GSLCC2) invert the DC power to two onshore AC grids at different locations.
To be concise, each wind farm is represented as an aggregated DFIG model rated at 2,000 MW. The two WFVSCs are both modeled as two-level converters with capacitor banks of 100 μF. Equivalent resistors and inductors in series are applied to represent the DC cables. The two GSLCCs are modeled as 12 pulse bridges rated at 2,500 and 1,500 MVA, respectively. Two onshore grids are represented as AC voltage sources with rated voltage of 230 kV and a short circuit ratio of 7 and 5, respectively. The parameters of the main components are shown in the Appendix.
3 Coordination control of the system
3.1 Overall control strategy
Coordination control among the wind farms and the converters must be achieved to guarantee satisfactory system performance. In this paper, the aim of the WFVSC is to control the offshore AC voltage amplitude and frequency; i.e., each WFVSC is controlled as an ideal AC voltage source, and thus it absorbs all generated wind power automatically. With a stable AC voltage, the DFIG captures the maximum wind power at various wind speeds through Maximum Power Point Tracking control based on the stator-voltage-oriented vector control method. On land, the GSLCCs stabilize the DC voltage, distribute the aggregated power to the onshore grids, and maintain the power balance of the MTDC system.
3.2 AC voltage control of WFVSCs
Modeling of the VSCs in the d–q rotating frame has been documented in [14, 15], and, therefore, no further details are given here. The controller shown in Fig. 2 is used for WFVSC1 and WFVSC2 to establish the AC voltage of the offshore grid. Rc and Lc are the equivalent resistance and inductance of the commutation reactor.
The controller is realized by aligning the d axis to the AC voltage space vector and it has two control loops, the outer voltage loop and inner current loop. In the outer voltage loops, the d axis voltage is set at the rated value, whereas the q axis voltage is set at 0, and the voltage difference is passed through a Proportional-Integral (PI) controller PI_o to generate current order for the inner loop. In the inner loops, ωLci qs and –ωLci ds are used to decouple the control between the d and q axes. The SPWM method with a switching frequency of 1,950 Hz is used to produce the trigger impulses for the IGBT valves.
3.3 DC voltage droop control of GSLCCs
Voltage droop control has been proposed to control the DC voltage and to dispatch the power in the VSC-MTDC systems [9, 16]. As the GSLCCs in the proposed system are designed to achieve similar functions, the droop control method could also be applicable.
The dynamic of an LCC can be expressed as
where Vdc is the DC voltage; Vi is the root mean square value of the AC side line-to-line voltage; β is the ignition advance angle; Idc is the DC current; Lc is the inductance; and ω is the angular frequency.
Idc is usually assumed to be constant and the time derivative of (1) is obtained as follows:
The error between the DC voltage and reference value is \( \Updelta V_{\text{dc}} = V_{\text{dc}} - V_{\text{dc}}^{ * } , \) and then (2) can be written as
Vi is usually at rated value. In addition, because β is usually less than 90° and varies little, sin β is assumed to be constant; thus, a PI controller can be designed to generate β to regulate the DC voltage error.
The DC voltage control of the GSLCC is shown in Fig. 3. The DC voltage difference is passed through a PI controller (PI2) to generate the ignition advance angle β. Moreover, a Voltage Dependent Current Control loop is added to the control system in order to improve system performance during transients.
For droop control, the DC voltage reference for each GSLCC is given by
where IGS is the DC current; VGS0 is the DC voltage when IGS is zero; and kGS is the slope of the droop characteristic.
Under droop control, when the DC voltage rises owing to unbalanced power, the GSLCCs will increase the DC currents and inverted power to the receiving grids, such that the DC voltage could be reduced. Thus, the requirement for fast communication between sending and receiving side converters could be negated.
In addition to DC voltage control, the GSLCCs could also distribute power between the AC grids according to pre-defined criteria. Figure 4 shows the simplified steady-state equivalent circuit of the MTDC system where only resistors are considered. RWF1, RWF2, RGS1, RGS2, and Rdc represent the equivalent DC resistances of cables 1–5, respectively.
It is assumed that the actual DC voltages can follow their references accurately through the control. From (4), the DC voltages of the GSLCCs are
The DC voltages at the intersection point of cables 3 and 4 can be expressed as
Substituting (6) into (5) yields
Hence,
The power shared between the two GSLCCs is
It can be concluded that the power distribution ratio could be regulated by adjusting the values of kGS.
3.4 System V–I characteristics in steady state
By applying droop control to each GSLCC and applying AC voltage control to each WFVSC, the V–I characteristics of all the converters can be obtained and are given in Fig. 5.
Straight lines LGS1 and LGS2 show the droop characteristics of GSLCC1 and GSLCC2. The solid curves CWF1 and CWF2 illustrate the characteristics of the WFVSCs. The two GSLCCs have the same VGS0 but different kGS. It is assumed that the DC voltages of the four converters are nearly of the same value: VWF1 = VWF2 = VGS1 = VGS2, represented as the solid horizontal line H1. The crossing points (W1, W2, G1, and G2) of H1 with LGS1, LGS2, CWF1, and CWF2 are the operating points of the converters. For power balance, the DC currents fulfill the condition IWF1 + IWF2 = IGS1 + IGS2.
When WF1’s power decreases, the V–I characteristic of WFVSC1 shifts to the dashed curve \( {\text{C}}_{\text{WF1}}^{'} \). With the decreased DC currents, each GSLCC reduces the DC voltage through the droop control, shown as the dashed horizontal line H2 in Fig. 5. As the wind power of WF2 remains unchanged, the current of the WFVSC2 increases a little. Finally, the system reaches a new steady state with DC voltages \( V^{\prime}_{\text{WF1}} = \,V^{\prime}_{\text{WF2}} \, = \,V^{\prime}_{\text{WF2}} \, = \,V^{\prime}_{\text{GS2}} \).
4 Simulation studies
Taking two GSLCCs’ capacities into consideration, the power sharing ratio between them is set at 5:3. Set VGS0 = 790 kV, kGS2 = 5.0 kV/kA, and from (9), kGS1 = 2.96 kV/kA. Other control parameters are shown in the Appendix. System performance has been tested in PSCAD/EMTDC. All simulation results on the DC side are per unit values based on 2,000 MW and 400 kV.
4.1 Black start-up
An offshore wind farm connected through a VSC-HVDC can realize black start-up, where the WFVSC’s capacitor is charged by the grid-side VSC with appropriate control [17]. However, it is different for the proposed hybrid system with the LCC working as the inverter whose current is mono-directional. In this case, an offshore auxiliary power supply (APS) or a DC line charger [18] is necessary to start the entire system.
In this paper, an alternative black start-up method without any APS is proposed. First, the WFVSCs’ DC link capacitors are charged through one GSLCC with reversed polarities, i.e., one GSLCC works as a rectifier in the beginning. After charging the capacitors of the VSCs through DC cables, the GSLCC’s polarities are switched to normal and work as an inverter, and then the entire MTDC system can be shifted into normal operation.
Figure 6 (left column) shows the simulation results under the designed start-up process. At the beginning, WF1 and WF2 both have an incoming wind speed of 11.5 m/s. WFVSCs are blocked, and the farm-side voltage has not been established. At 0 s, GSLCC1 is connected with reversed polarities and works in rectifying state with constant current control to charge the WFVSCs’ capacitors. Consequently, from Fig. 6c, the current and power of GSLCC1 are negative (power and current are positive when the WFVSCs send power to, or when the GSLCCs receive power from the DC side). At about 0.6 s, the capacitors’ voltages are charged to nominal value, and GSLCC1 is blocked. Then, GSLCC1’s polarities are switched to normal (the switching process is omitted in the simulation and is assumed to be accomplished in 0.5 s). Then, two WFVSCs are de-blocked, controlling farm-side voltages. DFIG are controlled to follow the voltages. At about 0.7 s, when the wind farm voltage is established as stable (Fig. 6b), the DFIGs are connected to the respective WFVSCs and at the same time the GSLCCs are de-blocked. With the increasing wind farm output power, the DC power transferred increases accordingly, and the entire system starts up smoothly, as expected. In Fig. 6d, the DC voltage references of the GSLCCs rise with the DC current, verifying the effectiveness of the droop control.
4.2 Wind speed variation
Assuming that WF1 and WF2 output rated power is stable prior to 3.0 s, a wind gust with a peak velocity of −2 m/s and duration of 2 s is applied to WF1 at 3.0 s.
Figure 6 (right column) shows the simulation results of the system under the disturbance of the wind gust. In Fig. 6b, the output power of WF1 decreases when the wind speed slows down, and consequently, the power transferred by the GSLCCs is reduced. Through the droop control, the DC voltage is reduced as the power transfer decreases (Fig. 6c). Figure 6d shows that the DC voltage of GSLCC1 follows the reference value well. Steady-state values of the power and the DC voltages of the two GSLCCs are summarized in Table 1. It can be seen that the power ratios between the two GSLCCs are very close to the defined value.
4.3 Disconnection of WFVSC1
Prior to 6.0 s, the two wind farms are both generating rated power. The two GSLCCs transmit the power according to the predefined ratio 5:3. At 6.0 s, WFVSC1 is disconnected from the MTDC network owing to converter failure. The main waveforms are given in Fig. 7.
From Fig. 7b, the sudden loss of WFVSC1 results in a sudden loss of 2,000 MW injected power and in a short-term decrease of DC voltage. As the AC voltage of WF2 is well controlled by WFVSC2, there seems little effect on WF2. The total injected power is reduced and is re-distributed between the GSLCCs. From Fig. 7b, it can be seen that the power ratio between the two GSLCCs is almost kept unchanged (PGS1:PGS2 = 0.56:0.34 = 4.94:3.0). With the reduced currents, the droop control of the GSLCCs decreases the DC voltage, as seen from Fig. 7c.
As seen from the simulation results, after the disturbance resulting from the disconnection of WFVSC1, the remaining system continues to operate stably with the pre-defined criteria being well maintained.
4.4 Disconnection of GSLCC2
The proposed hybrid MTDC system is vulnerable to DC short faults, because the WFVSCs’ capacitors will discharge instantaneously. Commutation failures, which resemble DC faults, will result in the direct connection of the valves in the same bridge arm. In both situations, the faults should be cut off immediately.
Assume that the four-terminal system is in stable operation prior to 10.0 s, and a three-phase-to-ground fault occurs on GSLCC2’s AC side at 10.0 s. Figure 8 shows the simulation results. With the severe drop of AC voltage, commutation failure occurs in GSLCC2.
Subsequently, the WFVSCs’ capacitors discharge through the DC cables and directly connected valves, resulting in DC rush currents. Once the low AC voltage and DC overcurrent (larger than three times normal current) are detected, GSLCC2 is blocked and the DC breaker connected to GSLCC2 opens with an action time delay of 5 ms and cuts off GSLCC2 from the DC system. Assuming that GSLCC1’s capacity is large enough to transmit all the wind power, the DC voltage can still be controlled well by GSLCC1, as seen in Fig. 8c. After a period of transients, the system goes to a new steady state with three healthy terminals.
5 Conclusions
This paper proposed a hybrid MTDC scheme for the integration of offshore wind farms and for wind power distribution. A hybrid four-terminal HVDC system has been constructed in PSCAD/EMTDC. The coordination control strategy and a novel black start-up method have been designed for the system. Simulation results show that:
-
(1)
The system could start-up smoothly, as designed, by reversing the GSLCC’s polarities.
-
(2)
By controlling the AC voltage on the offshore wind farm side, the WFVSCs could convert all generated wind power into the DC network.
-
(3)
DC voltage was well regulated by the GSLCCs and the expected power sharing was realized through voltage–current droop control of the GSLCCs.
-
(4)
Even under a severe disturbance caused by the disconnection of one WFVSC or of one GSLCC, the system remained operating stably.
It should be noted that although the research was based on a specific system with four terminals, the control methods of both sending side VSCs and receiving side LCCs could be applied to other similar hybrid MTDC systems with various numbers of terminals and different DC network configurations.
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Acknowledgments
This study was supported by National Natural Science Foundation of China (No. 50937002, No. 51190104) and National HI-Tech R&D Program of China (No. 2011AA05A112).
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Zhan, P., Li, C., Wen, J. et al. Research on hybrid multi-terminal high-voltage DC technology for offshore wind farm integration. J. Mod. Power Syst. Clean Energy 1, 34–41 (2013). https://doi.org/10.1007/s40565-013-0011-5
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DOI: https://doi.org/10.1007/s40565-013-0011-5