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Inter-regional transmission line fault often results in power flow transferring, tie-line overloading and system islanding. Traditional control methods such asgenerator tripping and load shedding are costly, and also have undesirable impacts on theloadside. In this paper, a new emergency power control strategy is proposed for multi-channel interconnected system by using the overload capacity of non-fault DC lines. First of all, the capacity of emergency power control can be acquired by critical transmission power of a certain tie-line for stability. Secondly, the shortest electric distance can be calculated by Dijkstra algorithm, and then the priority of emergency control of the DC lines can be obtained by the entropy weight method. When the inter-regional transmission power decreases and the effect of single DC line emergency control is poor, the multi-channel cooperative emergency control strategy is proposed to ensure the system stability. Simulation results verify the effectiveness of the method proposed.

With the rapid development of inter-area transmission connection, the capacity of transmission power increases greatly and the electrical interconnection distance between different areas become closer [

In order to improve the stability of system operation, multiple HVDC inter-area transmission lines operate in parallel. By the year 2014, three HVDC lines have been constructed connecting Southwest power grid to Huadong power grid while four HVDC lines transmitting power from Huazhong power grid to Huadong power grid. By the year 2018, Yu’e back-to-back HVDC line will be available, thus the connecting tie-line between Southwest power grid and Huazhong power grid will double. More inter-area HVDC tie-lines will be built in the future.

Despite of the benefit of HVDC multi-transmission lines, many challenges and potential risks occur at the same time. If a HVDC tie-line is tripped after a serious fault, it will definitely block a huge amount of power transmission and therefore result in power flow transferring. Many lines will trip because of the over loads and islanding devices may probably take action, separating the whole system into small islands. Then more loads will be lost later.

DC emergency power control technology can improve the capacity of power transmission after a block fault happens, and improve system transient stability [

In this paper, a new emergency strategy is proposed to solve the problem that if a HVDC line trips in multi-HVDC transmission system. First of all, a general description of the structure and stability analyses of multi-HVDC transmission system is given. Next, specific control methods such as the time point of start/ stop and the capacity of power control will be demonstrated. Furthermore, Dijkstra algorithm has been used to obtain the shortest electric distance, and entropy weight method is established to set the priority of controlling order. Finally, a complete emergency strategy based on multi-channel cooperation is presented and verified by simulations.

Regional power grids are often connected by multiple DC lines to improve transfer capability and stability. Typical structure of multi-channel interconnected system can be found in China as shown in

Huazhong power grid, connecting northwest power grid through Hazheng/ Lingbao HVDC lines to the west, connecting Huadong power grid through Genan/Longzheng/Linfeng/Yi hua HVDC lines to the east and connecting Huabei power grid synchronously through Changnan line to the north. Besides, another three HVDC lines (Fufeng/Binjin/Jinsu) connect southwest power grid to Huadong power grid, forming a typical hybrid AC/DC power grid configuration.

The power transmission capacity between Huazhong and Huadong power grid will decrease if a block fault happened in Longzheng HVDC line. A huge amount of power electricity will be blocked in Huazhong power grid, resulting in serious power flow transferring and severe power fluctuation on Changnan transmission line. The generator angle of Huazhong power grid gradually goes ahead, islanding devicescut off the Changnan synchronous line when the connected two areas cannot remain synchronous.

N-1 security criteria shows that power system can stand certain amount of disturbance such as the single line outage. According to N-1 security criteria, if one

of the interconnected channels is cut off after a fault, the whole interconnected system can remain synchronized if the capacity of transmission power is above a certain minimum value. This minimum value can be defined as the critical transmission power (P_{i,min}) for stability , and can be calculated through off-line simulation as follows.

To find the P_{i,min} of line i and reduce the transmission power of HVDC line i gradually as a disturbance, until the connected two system cannot keep synchronized. The critical remaining transmission power is P_{i,min} shown in

Suppose line I trips for the sake of a fault. If the other paralleling HVDC lines are able to transmit more power instantly than P_{i,min} in total as an emergency control, then the system can remain synchronized.

Therefore, we can get the power capacity of emergency control by Equation (1).

where P_{i,c} indicates the capacity of emergency control. To improve the effect of emergency control, the capacity is often a little bit more than P_{i}_{,min}, which means the value of

1) When to start

If the blocking faults happen on transmission lines, not only the generation angle will become different but also its operating point will deviate from the original one. Therefore, the emergency control should take effect as quickly as possible after the fault, otherwise, it will lose its effect.

To demonstrate the viewpoint above, the case of bipolar blocking fault in Longzheng HVDC is given. Linfeng HVDC line increases transmission power at different time point as emergency control. In Figures 5-7, it is shown that the later emergency control starts, the larger the relative angle, the lower bus voltage and the more severe power fluctuation will be. Emergency control will fail if it is started later than 2 seconds after the fault.

However, take the signal transmission time into consideration, the emergency control strategy is often demonstrated 0.3 second delay after the fault [

2) When to stop

To diminish the bad influence when regional relative angle swings back from the peak point, the regional relative angle should be monitored by the PMU devices on both terminals of Changnan transmission line, and a signal should be sent to stop the emergency control when the relative angle reach the peak point (shown in

To define the priority control order parameter, two aspects should be considered: HVDC available transmission power and the electrical distance.

1) HVDC available transmission power

HVDC available transmission power (ATP) indicates the overload capacity of non-fault DC lines. A normal HVDC line can sustain 1.5 times rated power overload for 3 to 10 seconds and 1.1 times up to 2 hours [

2) The shortest electrical distance

The electrical distance indicates the electrical contact among different nodes in a power system [

The SED problem can be deemed to find the shortest path of a certain network, where the impedance is the weight of lines. Then, SED of two nodes can be calculated by Equation (2) based on the Dijkstra algorithm.

where _{i}) indicates the weight of e_{i} as impedance of transmission line.

3) Prioritycontrol parameter (PCP)

When the block faults occurs on DC transmission line, the non-fault DC line with less SED and larger ATP should be assigned with the top priority. Less SEDindicates that non-fault DC line is near to the faulted line, which can limit power flow transferring to the minimum degree. While the DC line with “larger ATP” will be likely to transfer more power, contributing the system to reach P_{i,min} and remain synchronized. Then a prioritycontrol parameter (PCP) for synthesizing SED and ATP together is proposed based on entropy weight method, this procedure is shown as follows.

Firstly, normalize ATP and SED parameters to the same unit as

Therefore, the ratio of the two parameters above of line i can be derived as.

Thus the entropy of ATP and SED are available below

The weight w_{j} can be calculated as.

Finally, the factor PCP can be obtained as.

If the loss of inter-area transmission power is so huge that a single HVDC line cannot meet the requirement, the multi-channel emergency control strategy should be applied and coordinate all non-fault paralleling HVDC lines in a proper way. However, the total overload capacity of all the non-fault paralleling HVDC lines should be above P_{i,c} to make sure the emergency strategy is feasible.

Since the power increase of non-fault HVDC line is costly, the principle of the emergency control is to make full use of the overload capacity of each HVDC line and minimize the number of total controlled lines. Hence, those HVDC ranked at the highestpriority should operate at 1.5 times overload and the one ranked at second assumes the rest of transmission power requirement. The flow chart for the coordination is shown in

Two case studies are given by using power system analysis software package (PSASP). The structure of Triple HUA AC/DC hybrid transmission system in

A block on Fulong HVDC unipolar occurs at 1 s. Emergency control strategy

takes effect instead of traditional controlstrategy. Transmission line structure of Sichuan province is shown as

In this case, non-fault HVDC links are: non-fault unipolar of Fulong HVDC, Binjin HVDC and Jinping HVDC line. After calculating the SED and ATP of each link above, the priority control order can be made depending on PCP. Detailed results can be seen from

It can be seen that the highest priority of controlling HVDC is Binjin HVDC. The P_{i,min} of Fufeng HVDC can be get to 1400 MW through simulation. Then P_{i,c} should be 1950 MW (where the value of

Simulation works on the Three Gorges multi-channel cooperating strategy is done with a block on Longzheng HVDC bipolar occurring at 1 seconds. The transmission structure and parameters are given in

The P_{i,min} of Longzheng HVDC line is 1400 MW, then P_{i,c} should be 1820 MW (where _{i,c} is larger than the available overload of any single HVDC line, the multi-channel cooperating strategy should be established. Specifically, Linfeng and Yihua HVDC improve 1500 MW and 320 MW respectively at the same time, starting at 1.3 second and stopping at 4.12 second. From

Name of DC | SED | APT/MW | PCP | Priority order |
---|---|---|---|---|

Fufeng non-fault unipolar | 0 | 1200 | 0.2507 | 3 |

Binjin | 76.5 | 4000 | 0.5184 | 1 |

Jinsu | 75 | 3600 | 0.2771 | 2 |

SED | APT/MW | PCP | Priority order | |
---|---|---|---|---|

Linfeng | 36 | 1500 | 0.6243 | 1 |

Genan | 87 | 580 | 0.706 | 3 |

Yihua | 122 | 1500 | 0.2051 | 2 |

In AC/DC hybrid power system, a sudden huge decrease in inter-area transmission power will make the system collapse. A new emergency control strategy based on the overload capacity of HVDC line is proposed in this paper to enhance system stability and prevent out-of-step islanding. This emergency control should start as quickly as possible and stop at the first peak of regional relative angle. If the number of paralleling HVDC line is above three, the priority control order can be judged by entropy weight method considering SED and ATP. Besides, the multi-channel cooperating strategy should be applied if the demanding controlling capacity is huge.

Wang, Y.C., Shao, D.J., Zhang, Z.Q., Xu, Y.P., Pan, X.J. and Sun, H.S. (2017) DC Emergency Power Control Strategy for AC/DC Multi-Channel Interconnected System. Energy and Power Engineering, 9, 735-747. https://doi.org/10.4236/epe.2017.94B079