Design and Operation of a Hybrid Modular Multilevel Converter

Zeng, Rong; Xu, Lie; Yao, Liangzhong; Williams, B.W.

doi:10.1109/tpel.2014.2320822

Cited by 365 publications

(232 citation statements)

References 21 publications

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“…Each HB submodule employs 2 IGBTs, bypass switch and bypass thyristors which have lower costs and will be neglected in this study. According to (19) and (20), the relationship between the total number of IGBTs per arm and the k MMC is:…”

Section: MMC Power Capability Increase With Over-modulationmentioning

confidence: 99%

“…Successful HB submodule balancing demands that the arm current has positive and negative segments in each cycle. This implies that the peak of AC component in (34) must be larger than DC component: In steady state, the instantaneous dc power equals the AC power, and therefore using (8), (23) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 Therefore, for a FB-MMC with design requirement V minpu ≥0.5k MMC , the N FB and N HB can be dimensioned according to (19) and (20). For the other design requirement -0.5k MMC <V minpu <0.5k MMC , to enable successful voltage balancing of the submodule voltages all the inserted submodules should be of FB type.…”

Section: A Minimal Number Of Fb Submodules For Successful Voltage Bamentioning

confidence: 99%

“…Combining (19), (20), (39) and (40), generic method of calcuating the number of FB submodules and HB submodules in a FB-MMC under any specified design condition is: Fig. 4 shows the number of required FB submodules (in pu relative to the total number of submodules in an arm N sm ) as the function of V minpu (in pu relative to V dcn ) and k MMC .…”

Section: Page 4 Of 9 Ieee Pes Transactions On Power Deliverymentioning

confidence: 99%

See 2 more Smart Citations

Full bridge MMC converter optimal design to HVDC operational requirements

Lin

Jovcic

Nguefeu

et al. 2016

2016 IEEE Power and Energy Society General Meeting (PESGM)

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Abstract-Design and operation of FB (full bridge) MMC that meets HVDC specifications are studied in this paper. Three new design parameters: the over-modulation index (k MMC ), the DC modulation index (M dc ), the minimal DC voltage (V minpu ) are introduced to specify the operation of a FB MMC. Power increase and semiconductor count increase with the increase of k MMC is analyzed to understand benefits of over-modulation. The required number of submodules and the number of more-costly FB submodules for specified rated dc voltage, V minpu and k MMC are calculated. The relationship of the submodule inserting logic and dynamics of an arm is analyzed. The submodule voltage balancing is studied and the constraints on the required number of FB submodules are deduced. The capability of over-modulation and the operation under low DC voltage with optimal submodule count are verified using EMTP simulation.

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Section: MMC Power Capability Increase With Over-modulationmentioning

confidence: 99%

Section: A Minimal Number Of Fb Submodules For Successful Voltage Bamentioning

confidence: 99%

Section: Page 4 Of 9 Ieee Pes Transactions On Power Deliverymentioning

confidence: 99%

See 1 more Smart Citation

Full bridge MMC converter optimal design to HVDC operational requirements

Lin

Jovcic

Nguefeu

et al. 2016

2016 IEEE Power and Energy Society General Meeting (PESGM)

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show abstract

“…Hence, many MMC submodule topologies are developed based on the half bridge MMC, such as full bridge SMs [6] and clampdouble SMs [7]. Because the modified SMs have more losses during normal operation, the hybrid MMC is considered [8]. This second method has two types.…”

Section: Introductionmentioning

confidence: 99%

Fault Handling Methods and Comparison for Different DC Breaker Topologies and MMC Topologies of the HVDC System

Jiang

Bakran

2018

Advances in Power Electronics

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The HVDC system has many significant benefits and is widely used around the world. The protection of HVDC system is always an issue, which should be solved. This paper presents the working principle of different protection schemes. The advantages and disadvantages of these protection schemes are also introduced. In order to solve the HVDC fault, two protection strategies are proposed. One design focusses on the topologies of the HVDC breaker in the HVDC line, such as all-solid HVDC breaker, resonant HVDC breaker, and hybrid HVDC breaker. The other design is from the viewpoint of converter topology, which has two types. One type generates the counter-emf in arms, such as full bridge MMC, hybrid MMC, and clamp-double MMC. The other type cuts off the current path from the AC side to the DC side, which is also introduced in this paper. Some performances of these topologies are compared, such as switching time and efficiency.

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“…Thus, fast and reliable protection is mandatory for fast fault clearance to avoid complete shutdown of the entire network so as to minimize the disturbances to the connected AC networks. Some MMC topologies [15][16][17] can block or control DC fault current but resulting additional capital cost and power loss. In addition, such converter topologies cannot isolate fault from the MTDC network apart from protecting themselves from over-current so additional DC protection equipment is still required.…”

Section: Introductionmentioning

confidence: 99%

Protection of large partitioned MTDC Networks Using DC-DC converters and circuit breakers

Rahman

Yao

2016

Prot Control Mod Power Syst

Self Cite

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This paper proposes a DC fault protection strategy for large multi-terminal HVDC (MTDC) network where MMC based DC-DC converter is configured at strategic locations to allow the large MTDC network to be operated interconnected but partitioned into islanded DC network zones following faults. Each DC network zone is protected using either AC circuit breakers coordinated with DC switches or slow mechanical type DC circuit breakers to minimize the capital cost. In case of a DC fault event, DC-DC converters which have inherent DC fault isolation capability provide 'firewall' between the faulty and healthy zones such that the faulty DC network zone can be quickly isolated from the remaining of the MTDC network to allow the healthy DC network zones to remain operational. The validity of the proposed protection arrangement is confirmed using MATLAB/SIMULINK simulations.

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Design and Operation of a Hybrid Modular Multilevel Converter

Cited by 365 publications

References 21 publications

Full bridge MMC converter optimal design to HVDC operational requirements

Full bridge MMC converter optimal design to HVDC operational requirements

Fault Handling Methods and Comparison for Different DC Breaker Topologies and MMC Topologies of the HVDC System

Protection of large partitioned MTDC Networks Using DC-DC converters and circuit breakers

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