Monday, January 30, 2017

A breakthrough of HVDC circuit breaker in China: application and commercial services

Ever since the first Gotland HVDC link in 1954, islands have always been an exceptional testbed for HVDC technologies demonstration. The Zhoushan district in Zhejiang province, with more than 1300 islands and excellent wind resources, offers such a testbed in China to demonstrate new HVDC technology.

Back in July 2014, the island complex become the location for the first five-terminal multiterminal HVDC (MTDC) system, the Zhoushan ±200kV MTDC with Modular Multilevel Voltage Source Converters at each of the terminals.

In order to provide a truly multiterminal operation as a network it is important for the MTDC to have the ability to operate under dc and ac side faults and appropriately isolate faulted terminals. The key device to provide such functionality is the dc breaker.

In the end of 2016, the Zhoushan MTDC became the ground for another breakthrough in HVDC tehnologuy with the installation, commissioning and operation of the first 200kV circuit breaker  with fast isolation. The new circuit breaker is based on the combination of a high-speed mechanical switch and a hybrid cascaded full bridge module which allows fast extinction of bidirectional fault currents,on the dc side of the HVDC networks. The hybrid dc breaker is capable of isolating and disconnecting the dc transmission line for fault currents up to 15kA at 200kV within 3 ms.

Location of the five-terminal in google map : https://www.google.com.au/maps/place/Zhoushan,+Zhejiang,+China/@30.0124857,122.0165304,9.25z/data=!4m5!3m4!1s0x3452c5c61b6c087f:0xa95ffbbca9c810a6!8m2!3d29.985295!4d122.207216


The Zhoushan MTDC project connects the five MMC stations in five different islands by 134 km undersea cable, the overall capacity is 1000 MW. The MTDC has transmitted nearly 500 MWh since its first operation, and enlarges the ability of connecting distributed wind farms throughout the islands and improve the reliability of power supply for all islands.

‘Although VSC-HVDC as a technology has vast advantages, HVDC circuit breaker technology is a bottleneck in the electric engineering field’ said Jiejie Zhang, the vice director of department of HVDC, World Power Grid Research Institution, China.  VSC-based HVDC transmission networks, especially those based on the half-bridge MMC topology has no reliable ability to clear faults on the dc-side. Especially in the current implementation of the MTDC project, a partial fault in one converter station results in blackout in all converter stations leading to a reduced ability in avoiding cascading faults.

VSC-HVDC has significant advantages in MTDC systems as it enables independent control of active reactive power, and is expected to play a significant role in enabling bulk renewable energy integration, enhancement of flexible transmission systems. The application the hybrid breaker in the Zhoushan MTDC is an first step towards future DC transmission networks. 

Tuesday, January 24, 2017

Chongqing-Hubei back-to-back VSC HVDC: a hybrid interconnection

The National Development and Reform Commission of China formally gave its authorization for the construction of a "Back-to-back HVDC grid interconnection" between the Southwestern province of Chongqing and the Central province of Hubei. This authorization was approved on the 26th December, 2016.

Currently the interconnection between Chongqing and Hubei is through two 500kV AC transmission lines (Jiupan-Longquan & Zhangjiaba-Enshi) with the two systems connected and operating synchronously. Aiming to improve the stability of power transmission and the two systems , as well as to ensure the increasing electricity output from Southeast China, the State Grid Corporation of China (SGCC) decided to change the synchronous interconnection between the two systems into an asynchronous interconnection using HVDC.


Chinese main power grid 


The interconnections will be built using Voltage Source Converters (VSC) based on Modular Multilevel (MMC) converter technology. Compared with the ‘classic Current-Source Converter HVDC’, VSC-HVDC allows flexible control and fast response on both active power and reactive power respectively allowing decoupling and independent control of active and reactive power (PQ decoupling), avoids commutations failures typical with larger thyristor based systems and avoids the use of large reactive power compensators at the end of the HVDC lines.  

Each of the VSC-HVDC stations will be rated at 2*1250 MW with a DC transmission line voltage of ±400kV, it will be the one of highest voltage and largest capacity Back-to-back VSC-HVDC worldwide. With regards to technical parameters of the project, the converter station in the north lane located in Yichang city, Hubei province, will comprise two converter units at 1250 MW each and will be built in the second stage of the project with an overall capacity of 2500MW.  The B2B converter station in the south lane will be located in the City of Enshi, and will be of identical size and capacity to the North one. The AC system around the HVDC converters is of 500kV. 

The total cost of the project is estimated at 6.5 billion RMB (1.3 Billion AUD)

The following is a single line diagram of the proposed B2B VSC-HVDC station on the north transmission line:


 Geographical map of Project 



Saturday, January 21, 2017

The Ximeng-Taizhou ±800kV UHVDC (One of Four UHVAC & UHVDC Project) is nearing completion

The converter stations at the Ximeng-Taizhou UHVDC Project are nearing completion with 70% of main devices already installed and the overall project expected to reach completion by this Chinese Spring Festival (28th January 2017).

Figure 1 Converter station (from Xinhua Network)

This project is a significant component of the ‘Four UHVAC & Four HVDC plan’ as part of the broader ‘National Air Pollution Control Action Plan’. The ±800kV UHVDC Transmission line starts at the Ximeng converter station, located in the Inner Mongolia Autonomous Region and terminates at the Tazhou converter station, crossing five provinces (Inner Mongolia, Hebei, Tianjin, Shandong, Jiangsu), covering an overall distance at 1620km.  Commissioning and testing is expected to be completed by June, 2017, and the whole system will be operational by August.

Upon its completion, the Ximeng-Taizhou UHVDC Project will have the ability to transmit 55 billion KWh annually, equally transport 25 million tons, and reducing  CO2 emissions by 49.5 million tons. The project will contribute to the control of air pollution in the Yangtze district.



Figure 2 Construction of converter station

Driven by increased concerns about pollution and air quality, especially in the North-eastern provinces, Premier Li Keqiang hosted, on 18th April 2014, the first conference of the National Energy Committee, that led to the implemention of the  ‘National Air Pollution Control Action Plan’, and authorized construction of the “Four UHVAC & Four UHDC' Project, to "improve reliability of electricity supply, boost development of clean energy, contribute to a sustainable growth of the economy".

The whole project is expected to cost 174.48 billion RMB (34.2 billion AUD), and included construction and expansion of 10 high voltage converter stations and 15 high voltage substations transformer capacity reaches 140 million kWh. The overall transmission line length of all the projects is above 12,000 km, with all eight transmission lines expected to come into service within 2017.

The following are the details of the eight transmission lines of the “Four UHVAC & Four UHDC' Project.

Name
Voltage
Distance(km)
Capacity (MW)
Operation Time
Status
1 Huainan-Nanjing-Shanghai
1000kV
UHVAC
2*789
12000
2016
In Operation
2 Ximeng-Shandong
1000kV
UHVAC
2*730
15000
2016
In Operation
3 Mengxi-Tianjin
1000kV
2*608
24000
2016
In Operation
4 Yuheng-Weifang
1000kV
UHVAC
2*1049
15000
2017
Under
Construction
1 Ningdong-Zhejiang
±800kV UHVDC
1720
16000
2016
Under
Construction
2 Jinbei-Nanjing
±800kV UHVDC
1119
16000
2017
Under construction
3 Shanghaimiao-Shandong
±800kV UHVDC
1300
12800
2017
Under construction
4 Ximeng-Taizhou
±800kV UHVDC
1620
14400
2017
Under constrcution


Figure 3 Paths of the 'Four UHVAC & Four UHVDC' Project



Wednesday, January 18, 2017

Construction begins in the World's longest power transmission project, the ±1100KV Changji-Guquan UHVDC


On the 4th January 2017, the assembly of the first transmission tower in the ±1100KV UHVDC  Changji-Guquan project was completed. The tower will support the 3324km UHVDC transmission line as it crosses the Qinling Mountains, the west-east range that crosses the Shaanxi province, in the NorthWest of China.



Figure 1. UHVDC Transmission Tower (Source: Xinhua WANG)

This project is the one of most advanced Ultra High Voltage DC transmission projects globally, an the first at 1100kV transmission voltage, also breaking the records for largest transmission capacity, and longest transmission distance. The project is part of the Chinese Government's strategy for ‘transmitting power from the West to the East of China’. It has ability to transmit 66 billion KWh annually, which equal reducing coal transport around 30.24 million tones, declining 59.4 million tones CO2, above all it reducing the dependence of fossil-fuel based power plants in Eastern China.



Figure 2 Changji - Guquan UHVDC transmission line route (Source: Zhundong)

A converter station with capacity at 24000 MW, will be located in Changji, Xinjiang Autonomous Region in the West of China and the 3324 km transmission line will cross five provinces (Gansu, Ningxia, Shanxi, Henan) delivering power to the Anhui province in the East with the second converter station located in Guquan. The project is currently under way with the assembly of the transmission towers, and is expected to be completed in May of 2018.





-Dezhen,ZHANG