What is a hydrogen energy storage system in a microgrid?

The hydrogen energy storage system within the microgrid consists of an electrolyzer, a hydrogen storage tank, a fuel cell stack, and two DC/DC converters. The buck converter allows the EL to consume the electric power to produce hydrogen, which is stored in the HST.

How does a microgrid energy storage system work?

The electric energy storage system uses a supercapacitor module, which is connected to the bus with a bidirectional buck-boost converter for consuming or supplying the electric power. The hydrogen energy storage system within the microgrid consists of an electrolyzer, a hydrogen storage tank, a fuel cell stack, and two DC/DC converters.

Can a microgrid be used as a hydrogen chain?

Within the microgrid, three hydrogen components are employed: electrolyzer (EL), hydrogen storage tank (HST), and fuel cell (FC). On the other hand, the microgrid as a whole can be taken as a hydrogen production and storage unit. Therefore, this paper further investigates the microgrid in the context of a hydrogen chain.

Can a microgrid produce hydrogen?

On top of properly managing the energy within the microgrid, the production, storage, transportation, and utilization of hydrogen also need to properly coordinated. In fact, islanded or grid-connected microgrids can be used to produce hydrogen or even serve as a hydrogen refueling station if configured properly.

How to manage power and hydrogen flows within a microgrid?

To manage the power and hydrogen flows within the microgrid and coordinate the coupling between the microgrid and the hydrogen refueling station, this paper proposes an energy management framework for the electric-hydrogen system shown in Fig. 1 based on two preliminary studies , .

How does a hydrogen refueling microgrid work?

Specifically, the outer layer determines the flow rate of the hydrogen transported from the microgrid to the hydrogen refueling station (i.e., W c p) and the power consumed by the hydrogen compressor (i.e., P l o a d c p). The inner layer optimizes the power allocation between the electric and hydrogen systems within the microgrid.