Your search keyword '"Sun, Kaiqi"' showing total 3 results

1. An optimal combined operation scheme for pumped storage and hybrid wind-photovoltaic complementary power generation system.

Author

Sun, Kaiqi, Li, Ke-Jun, Pan, Jiuping, Liu, Yong, and Liu, Yilu

Subjects

*SOLAR wind, *SOLAR energy, *ELECTRIC power distribution grids, *PRODUCTION control, *IDEAL sources (Electric circuits)

Abstract

• An optimal combined operation scheme for pump storage and wind-pv system is proposed. • Real-time coordinated control enabling automatic dispatch of the pump storage. • The power production fluctuations of wind-pv system is reduced with proposed scheme. • The revenue of hydro wind-pv system is significantly improved with proposed scheme. Because of the steady increase of wind and solar capacity installations in recent years, the goal of the Paris Agreement is expected to be reached. However, due to the intermittent characteristics of renewable generation, challenges are presented for the power grid to operate reliably and economically under the high uncertainty of wind and solar power productions. Sufficient responsive reserves must be available for the power grid to maintain the balance between the supply and demand. To be fair to the market participants, the renewable generation companies should pay for the received grid ancillary services. In this paper, an optimal combined operation scheme is proposed for pumped storage hydro and hybrid wind-photovoltaic complementary power generation system interconnected by a Voltage Source Converter-based multi-terminal HVDC system. The optimal combined operation scheme has two real-time control functions. The pumped storage hydro control function enables automatic dispatch of the pumped storage hydro to effectively suppress or compensate for the output deviations of wind and solar generation from the forecasted production; and the output control function is able to distribute the non-compensated production surplus or deficit to different ac systems based on the market regulating service prices. A Case study is provided to demonstrate the improved power generation profile and reduced revenue losses of the pumped storage hydro and hybrid wind-photovoltaic complementary power generation system. [ABSTRACT FROM AUTHOR]

Published

2019

2. Operation Zone Analysis of the Voltage Source Converter Based on the Influence of Different Grid Strengths.

Author

Wang, Wenning, Li, Kejun, Sun, Kaiqi, and Wang, Jianjian

Subjects

IDEAL sources (Electric circuits), VOLTAGE-frequency converters, ELECTRIC power system stability, ELECTRIC networks, SHORT circuits, RENEWABLE energy sources

Abstract

With the increasing penetration of renewable energy into the power system, the voltage source converter (VSC) for integrating renewable energy has become the most common device in the electric network. However, the operating stability of the VSC is strongly dependent on its operating control strategy, which is also highly related to the strength of the AC system. Choosing the control strategy of VSC for different strengths of AC systems becomes an essential issue for maintaining the symmetry between high proportion of renewable energy integration and stable operation of AC system. In order to obtain the operation zones of the control strategies of the VSC under different strengths of AC system, in this paper, the two common VSC control strategies, vector current control (VCC) and power synchronization control (PSC), are compared. Firstly, the principle of VCC and PSC are introduced. Then, based on the short circuit ratio (SCR) and the power limit calculation under steady-state conditions of the VSC, the operation zones of the vector current control and power synchronization control are proposed. Finally, a medium voltage modular multilevel converter (MMC) system was built in PSCAD/EMTDC and the proposed operation zones of the VCC and PSC were tested by changing the SCR of the modified IEEE 33 bus system and analyzed via the critical short circuit ratio (CSCR) analysis, the small-signal stability analysis, and transient stability analysis. The results indicate that, as the SCR decreases, the VSC based on VCC is gradually worked into unstable conditions, while the stability of VSC based on PSC gradually increases. The analysis results provide a criterion for the converter operation strategy change that could significantly improve the operating stability of the VSC in the power system and realize the symmetry of the stability of the converter and the change of the strength of the AC system. [ABSTRACT FROM AUTHOR]

Published

2022

3. Review of hybrid HVDC systems combining line communicated converter and voltage source converter.

Author

Xiao, Huangqing, Sun, Kaiqi, Pan, Jiuping, Li, Yujun, and Liu, Yilu

Subjects

*VOLTAGE-frequency converters, *IDEAL sources (Electric circuits), *HYBRID systems, *POWER transmission, *HYBRID zones

Abstract

• A review of four LCC-VSC hybrid HVDC topologies is proposed. • The PQ operating zone of the four hybrid HVDC topologies is investigated. • The power flow reversal comparison of the four hybrid HVDC topologies are achieved. • The DC fault ride-through strategy of the four hybrid HVDC topologies are studied. Hybrid HVDC system, which consists of the advantages of line commutated converter (LCC) and voltage source converter (VSC), is an emerging power transmission system. This paper presents a review of four LCC-VSC hybrid HVDC topologies. The first topology is the pole-hybrid HVDC system, in which the LCC and VSC form the positive- and negative-pole respectively. The second one is the terminal-hybrid HVDC system; in this topology one terminal adopts LCC and the other terminal adopts VSC. The series converter-hybrid HVDC system is the third topology wherein each terminal is formed by LCC and VSC in series. The fourth hybrid topology under consideration is a parallel converter-hybrid HVDC system with LCC and VSC connected in parallel in each terminal. The main contribution of this paper is a comprehensive analysis and comparison of the four mentioned hybrid topologies in terms of PQ operating zone, power flow reversal method, and DC fault ride-through strategy. [ABSTRACT FROM AUTHOR]

Published

2021