Meitan xuebao (Apr 2023)

Key technologies and bottlenecks of multi-energy complementary DC microgrid for residual coalbed methane drainage in abandoned mine

  • Hao WANG,
  • Bin LI,
  • Yuting WANG,
  • Shaoling LI,
  • Guopeng ZHANG,
  • Dashan YANG,
  • Lijun BAI,
  • Cong WANG

DOI
https://doi.org/10.13225/j.cnki.jccs.2022.1289
Journal volume & issue
Vol. 48, no. 4
pp. 1798 – 1813

Abstract

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In terms of the collaborative utilization of residual energy and space resources in abandoned mines, under the framework of a green low-carbon multi-energy complementary system, a multi-energy complementary DC microgrid integrating wind-solar-gas-storage for residual CBM drainage in abandoned mine was proposed and constructed with the consideration of both the electricity demand of coalbed methane (CBM) in the abandoned mine goaf and the power generation potential of renewable energies in coal mining subsidence areas, as well as the low-concentration gas power generation and energy storage as supplements. Compared with the common DC microgrids, the superposition of multiple unfavorable factors such as low system inertia, weak grid connection, random changes in distributed power generation and large fluctuations in periodically variable working condition load makes the stable operation of the multi-energy complementary DC microgrid for residual CBM drainage face become a more severe challenges. Therefore, it is necessary to systematically discuss and investigate the key technologies and bottlenecks involved in the multi-energy complementary DC microgrid for residual CBM drainage in abandoned mine which is a potential scenario of collaborative utilization of residual energy and space resources in abandoned mines. First, the topology and components of a multi-energy complementary DC microgrid for residual CBM drainage were described, and the constraints that need to be considered in the system capacity optimization were discussed based on an energy flow model. Then, the key technologies including periodically variable working condition load analysis of CBM pumping motor, coupling of gas-electric conversion link of low-concentration gas generator, voltage stabilization control and system coordinated operation involved in achieving reliable, stable and coordinated operation of multi-energy complementary DC microgrid for residual CBM drainage in abandoned mine were concluded. The recent research progresses were summarized and reviewed, the difficulties and problems existed in the current work were analyzed, and some possible solutions and suggestions for following work were discussed. Furthermore, it is pointed out that it is urgent to address the bottleneck issues behind the key technologies such as the joint modeling method of both gas-electric coupling long-time scale of the low-concentration gas generator and short-time scale of wind-solar-storage, as well as the bus voltage oscillation mechanism caused by multiple unfavorable factors such as low inertia, weak connection and large disturbance. Finally, the feasibility and application prospect of constructing a multi-energy complementary DC microgrid for residual CBM drainage in abandoned mine were prospected from the aspects of existing work basis, research progress and economic benefits assessment.

Keywords