Description

Nowadays, an important kind of islanded microgrids can be found in maritime power systems. For example, under normal operating conditions, the ship power system can be considered as a typical isolated microgrid and its characteristics, including variable frequency, are matched to terrestrial islanded microgrids.

This course provides an overview of the present and future architectures of such microgrids, associated control technologies, optimization methods, power quality issues and state of the art solutions. The significant role of power electronics in realizing maritime microgrids, challenges in meeting high power requirements and regulations in the maritime industry, state-of-the-art power electronic technologies and future trend towards the use of medium voltage power converters in maritime microgrids are also presented in this course.

Find the detailed course program on PhD Moodle: phd.moodle.aau.dk/course/view.php?id=2190 

Prerequisites

 The course exercises will be done via Matlab/Simulink simpowersytems.

Form of evaluation

The participants will be grouped and asked to team work on several case study scenarios and tasks proposed along the course. The assessment in this course will be done through a final multi-choice test in combination with delivery of exercises reports

Price

8000 DKK for the Industry and 6000 DKK for PhD students outside of Denmark (VAT-FREE Education)

The Danish universities have entered into an agreement that allows PhD students at a Danish university (except Copenhagen Business School) the opportunity to free of charge take a subject-specific course at another Danish university.
Read more here: https://phdcourses.dk/           

Questions

hr@energy.aau.dk   

More information

https://www.energy.aau.dk/research/phd   

Course literature       

1. z. jin, l. meng, j. m. guerrero and r. han, "hierarchical control design for a shipboard power system with dc distribution and energy storage aboard future more-electric ships," in ieee transactions on industrial informatics, vol. 14, no. 2, pp. 703-714, feb. 2018.
2. c. -l. su, j. m. guerrero and s. -h. chen, "happiness is a hybrid - electric: a diesel-burning boat finds new life with a direct-current microgrid," in ieee spectrum, vol. 56, no. 8, pp. 42- 47, aug. 2019.
3. z. jin, g. sulligoi, r. cuzner, l. meng, j. c. vasquez and j. m. guerrero, "next-generation shipboard dc power system: introduction smart grid and dc microgrid technologies into maritime electrical netowrks," in ieee electrification magazine, vol. 4, no. 2, pp. 45-57, june 2016
4. w. liu et al., "power quality assessment in shipboard microgrids under unbalanced and harmonic ac bus voltage," in ieee transactions on industry applications, vol. 55, no. 1, pp. 765-775, jan.-feb. 2019.
5. l. hong, q. xu, z. he, f. ma, a. luo and j. m. guerrero, "fault-tolerant oriented hierarchical control and configuration of modular multilevel converter for shipboard mvdc system," in ieee transactions on industrial informatics, vol. 15, no. 8, pp. 4525-4535, aug. 2019.
6. x. zhaoxia, z. tianli, l. huaimin, j. m. guerrero, c. -l. su and j. c. vásquez, "coordinated control of a hybrid-electric-ferry shipboard microgrid," in ieee transactions on transportation electrification, vol. 5, no. 3, pp. 828-839, sept. 2019.
7. m. a. hassan et al., "dc shipboard microgrids with constant power loads: a review of advanced nonlinear control strategies and stabilization techniques," in ieee transactions on smart grid, 2022
8. luona xu, et al, "a review of dc shipboard microgrids – part i: power architectures, energy storage and power converters," ieee transactions on power electronics, 2022.
9. luona xu, et al, "a review of dc shipboard microgrids – part ii: control architectures, stability analysis and protection schemes," ieee transactions on power electronics, 2022.
10. bakar, n. n. a., guerrero, j. m., c vasquez, j., bazmohammadi, n., othman, m., rasmussen, b. d., & al- turki, y. a. (2022). optimal configuration and sizing of seaport microgrids including renewable energy and cold ironing—the port of aalborg case study. energies, 15(2), 431.
11. bakar, n. n. a., guerrero, j. m., vasquez, j. c., bazmohammadi, n., yu, y., abusorrah, a., & al-turki, y. a. (2021). a review of the conceptualization and operational management of seaport microgrids on the shore and seaside. energies, 14(23), 7941.
12. ericsson, p. (2008). shore-side power supply-a feasibility study and a technical solution for an on- shore electrical infrastructure to supply vessels with electrical power while in port (master's thesis).
13. “iec/ieee international standard - utility connections in port -- part 2: high and low voltage shore connection systems -- data communication for monitoring and contro,” iec/ieee 80005-2 ed. 1.0 2016-06, pp. 1–116, 2016, doi: doi: 10.1109/ieeestd.2016.7500035
14. d. colarossi, g. lelow, and p. principi, “transportation research interdisciplinary perspectives local energy production scenarios for emissions reduction of pollutants in small-medium ports,” transp. res. interdiscip. perspect., vol. 13, p. 100554, 2022, doi: 10.1016/j.trip.2022.100554.
15. y. peng, x. li, w. wang, k. liu, x. bing, and x. song, “a method for determining the required power capacity of an on-shore power system considering uncertainties of arriving ships,” sustain., vol. 10, no. 12, 2018, doi: 10.3390/su10124524.
16. n. nikitakos and t. e. lilas, “shore side electricity and renewable energy potential at igoumenitsa port shore side electricity and renewable energy,” no. july 2017, 2015.