How New Technology Benefits Microgrids
Image source: Viktoria Kurpas/shutterstock.com
By Paul Lee for Mouser Electronics
Edited March 18, 2021(Originally Published August 17, 2020)
Microgrids have been around for a long time in some form or another. The farmer that fired up his diesel
generator in the early 20th century to keep his irrigation pumps and house lights working when the utility
supply failed might not have recognized the term. Still, he was setting up what is now the definition of a
microgrid–a group of locally interconnected loads and an energy source that can operate independently of
the national grid.
Marketers have had fun with the nomenclature as usual, with macro- used for the main grid, milli- for larger
installations or collections of independent grids, micro- and even nano-grids that might be no more than a
backpack-mounted solar panel topping up your cellphone on a hike.
The microgrid is an area of intense interest today, typically powering an installation such as a farm, remote
factory, hospital, or military site. With a global market projected to be around $47.4 billion (USD) in 2025 at
a compound annual growth rate of more than 10 percent, a microgrid can be fully independent or islanded, a
backup for the main grid on failure or even a contributor to the main grid when locally-sourced energy is in
excess of local needs.
The drivers for the use of microgrids are power for remote locations where no utility infrastructure is present,
resilience against main grid failure, and flexibility to use local renewable energy sources such as hydro,
solar, wind, ground-sourced, and combined heat and power (CHP), for a smaller environmental impact and reduced
costs. Security is also a growing concern, especially for critical installations such as data centers,
hospitals, and military bases where cyberattacks on the main utility supply are real possibilities. Here,
we’ll review types of microgrids and power-conversion arrangements and the benefits of each.
A Smart Microgrid Is Key to Effectiveness
A domestic microgrid arrangement might look like Figure 1, with fixed solar panels replacing or
contributing to utility power via an inverter synchronized to the main grid. A high-capacity lithium-ion or
lithium-iron-phosphate battery might be kept charged and available to provide power after dark or backup if the
main power fails. Alongside typical household loads such as lighting, heating, and kitchen/utility equipment,
electric vehicle recharging is increasingly in the mix. Ideally, it should be from a local renewable energy
source such as solar to retain its green credentials. Smart control, personalizing the microgrid installation,
squeezes the maximum efficiency from solar panels while scheduling loads for minimum impact. Excess energy can
be automatically returned to the main grid, either from the solar panels or even from the EV battery, for
utility load balancing in return for monetary credit.
Figure 1: A typical domestic microgrid arrangement. (Source: Mouser
Electronics)
A factory would have a more complex microgrid arrangement, perhaps with multiple energy sources, as in
Figure 2. The cost-benefit analysis for a factory environment is more complex than for a
domestic situation. ; Lost production during a blackout is a real cost, and extra productivity and lower energy
costs from a smart environment are real benefits.
Figure 2: A typical microgrid arrangement in a factory environment. (Image
reproduced with the permission of Rolls-Royce Power Systems AG)
The diagram shows how various renewable energy sources such as wind and solar can be coupled with traditional
generator sets to provide complete independence in electrical power and heating when demanded, all under
intelligent control with wireless communication. The system can integrate with the Industry 4.0 or Industrial Internet of Things
(IIoT) concept. This combines physical production and operations with smart digital technology, machine
learning, and big data to create a more holistic and better-connected ecosystem for companies that focus on
manufacturing and supply chain management. Careful consideration must be given both in domestic and
industrial applications to the microgrid architecture, not just for functionality but also for electrical
efficiency, to achieve the hoped-for energy savings.
Power Conversion Efficiency Critical to Payback
Even in the relatively simple domestic installation of Figure 1, electronic power conversion has
multiple stages: The solar panels’ output DC must be converted to the storage battery voltage using an
intelligent DC-DC converter with Maximum Power Point Tracking (MPPT) to extract maximum energy, an inverter
transforms the battery DC to AC line voltage, a battery charger ensures that the battery is maintained at full
capacity when solar input is not available, and a bidirectional converter charges the EV battery from AC but
transfers power in reverse, typically at night. Other possible power sources have their power conversion
requirements, such as a wind turbine with an induction generator that outputs variable frequency and amplitude
AC, converted into utility-compatible levels. In an industrial environment, of course, complexity is much
higher.
All these power conversion stages lose some energy as heat representing money lost and longer payback times, so
efficiency is a major concern. In some situations, heat can be recovered, perhaps for community use. The
opportunities are limited, so it is more likely that even more energy and cost are expended in cooling systems
to extract the heat and avoid stress on the power conversion electronics.
New Semiconductors Control Cost, Size, Savings
The various power conversion stages in a microgrid all use switched-mode techniques–semiconductor switches
chop the input DC or rectified AC voltage at high frequency, followed by a relatively small transformer to scale
the voltage back to DC through rectifiers, or to AC through filters. Regulation of outputs to a constant DC or
50/60Hz AC is achieved by Pulse Width Modulation (PWM) of the semiconductor switching action.
At higher powers, choice of semiconductor switch has been limited until recently to insulated-gate bipolar
transistors (IGBTs), which must be switched relatively slowly for acceptable efficiency: IGBTs dissipate no
power when they are off and have some conduction loss when on, but as they transition between the two states,
they can take transient power that can be measured in kilowatts (Figure 3). The more
transitions per second (frequency), the higher the dissipation. For this reason, switching frequencies have been
a few tens of kHz at most, and this has implications down the line; transformers and other magnetic components
such as filters have to be large and are consequently costly.
Figure 3: Power dissipation can be high during semiconductor switch
transitions. (Source: Mouser Electronics)
Increasing switching frequency has been a design goal for power converter designers for the size and cost savings
that follow, so other semiconductor devices have been considered that show lower switching losses, with MOSFETs,
the main contender. However, these devices have limited power ratings, and conduction losses can be higher than
IGBTs–MOSFETs exhibit an on-resistance that dissipates power with the square of the current value. IGBTs
exhibit a relatively constant voltage drop, so dissipation is approximately proportional to current. Therefore,
at high currents, MOSFETs can be lossy, and the benefits of higher frequency operation negated when the energy
lost and the larger, costlier cooling needed is factored-in.
A new generation of switches, wide band-gap (WBG) semiconductors, has become available, showing a step
improvement in switching speed without compromising efficiency. The devices, fabricated in silicon carbide (SiC)
and gallium nitride (GaN), can switch so fast than traditional silicon that any transient dissipation is
minimal. Combined with very low on-resistances and inherent high-temperature capability, equipment designed with
WBG technology is smaller and more efficient, not just because of the devices themselves but also because the
higher switching frequency enables smaller associated components such as transformers and filters. This all
reads directly across to low acquisition and running costs, quick payback, and a smaller environmental
footprint. Companies such as CREE, GaN Systems, UnitedSiC, Transphorm, and many others are active in the WBG
semiconductor field with devices available from Mouser Electronics.
Conclusion
Microgrids have the benefits of independence, resilience, security, and ability to maximize local renewables.
Microgrids can power an installation such as a farm, remote factory, hospital, or military site. Their
versatility and continued development, are reasons for the microgrid industry’s growth to reach around
$47.4 billion (USD) by 2025.
Author Bio
Paul Lee is the author
of over 200 articles and blogs on power subjects as well as a book on power supply design techniques: 'Power
Supplies Explained'. As a chartered engineer and with a degree in electronics, Lee has owned a power supply
manufacturing company and later worked as a Director of Engineering for Murata Power Solutions. Currently he is
a freelance writer and manages the European Power Supplies Manufacturers' Association. Lee lives in Oxfordshire
UK, is an associate of the Royal Photographic society and holds an amateur radio license.
