IEEE Power & Energy Magazine - Grid Edge 2023 - 78

EirGrid in Ireland and National Grid in Great Britain have
shown that these challenges increase dramatically when
IBPSs serve more than 65% of the system load.
Although large synchronous areas such as continental
Europe (CE) may not reach percentages as high in
the next 10 years, parts of these synchronous areas (such as
Germany or Denmark) are already experiencing situations
when IBPSs serve a significant portion of their local load,
in some cases in excess of 100%. The reliable operation of
such systems currently depends on support from the rest of
the synchronous area. Following the occurrence of a lowprobability,
high-consequence event such as system separation
(e.g., a 4 November 2006 event in CE), these smaller
parts of the larger synchronous area require the ability to
avoid a total collapse. As depicted in Figure 1, the forecast
from 2016 shows that the highest IBPS penetration level in
eight of 33 European countries would reach 100% of the load
by 2025. These instantaneous penetration levels could typically
be three to five times higher than the annual average
penetration levels.
A large presence of online SGs inherently slows the overall
system dynamic changes, which allows present grid-following
(GFL) IBPSs (that have fast and rigid controllers) to accurately
track the angle of the grid voltage and inject current at the correct
phase angle and frequency. However, as IBPSs replace
SGs, system dynamic changes become faster, resulting in the
rigid fast inverter controllers potentially failing to adequately
synchronize with the system. Based on control theory, only
an even faster controller can track a fast-moving reference.
At these fast response timescales and with rigid control, even
a small perturbation can result in significant consequences;
these will be discussed in subsequent sections. Thus, as IBPS
100
110
10
20
30
40
50
60
70
80
90
penetration increases, the controllers must respond more
robustly to a system with faster dynamics.
Currently, for secure operation, some synchronous areas
(e.g., Ireland, Texas, and South Australia) frequently limit the
output of IBPSs or require sufficient must-run SGs. Installing
synchronous condensers (SCs) to provide the characteristics
necessary to support reliable operation with very high IBPS penetration
has also been pursued, since maintaining a sufficient
number of SGs online is often difficult and expensive. In the
long run, operational constraints and the need for additional
investments into SCs could significantly affect further development
of IBPSs.
In recent years, the research community has pursued
the concept of grid-forming (GFM) IBPS technology as an
alternate robust IBPS controller. However, constructing an
exact definition of a GFM IBPS is complex, as the characteristics
are still being shaped in concert with the changing
needs of power systems around the world. For the purpose
of this article, a GFM IBPS broadly refers to an IBPS
that is capable of supporting the operation of an ac
power system under normal, disturbed, and emergency
conditions without having to rely on services from SGs
or SCs. This includes system conditions when 100% of the
electricity demand is supplied from IBPSs and situations
with very low IBPS penetration as well as transitions
between the two. More specifically, it would be desirable
for a GFM IBPS to have the following functionality:
1) Under normal (small-signal) conditions, it behaves as
an ac voltage source (the voltage behind impedance)
while respecting its internal physical limitations. The
control and associated settings of this voltage source
should be designed depending on the power system
to which it is connected.
2) It works autonomously if it is
isolated from the bulk power
system.
3) Under transient conditions, it behaves
as described in 1) but may
temporarily fall into a specific
operation regime to respect its
own limits. However, as soon as
the limits are not at risk of being
violated, it must return to the
behavior described in 1).
figure 1. A 2016 forecast of the highest hourly penetration levels of IBPSs in Europe
by 2025.
78
ieee power & energy magazine
4) Similar to select SGs contracted
to provide black start services at
present, some GFM IBPSs are
expected to have a sufficient
energy buffer (battery storage,
possibly coupled with a supercapacitor)
to initiate system
restoration after a blackout,
while others should be capable
of supporting the grid-restoration
process.
november/december 2019
(%)
Austria
Bosnia and Herzegovina
Belgium
Bulgaria
Switzerland
Czech Republic
Germany
Denmark
Estonia
Spain
Finland
France
Great Britain
Greece
Croatia
Hungary
Ireland
Italy
Lithuania
Latvia
Montenegro
Macedonia
Northern Ireland
The Netherlands
Norway
Poland
Portugal
Romania
Serbia
Sweden
Slovenia
Slovakia

IEEE Power & Energy Magazine - Grid Edge 2023

Table of Contents for the Digital Edition of IEEE Power & Energy Magazine - Grid Edge 2023

Contents
IEEE Power & Energy Magazine - Grid Edge 2023 - Cover1
IEEE Power & Energy Magazine - Grid Edge 2023 - Cover2
IEEE Power & Energy Magazine - Grid Edge 2023 - Contents
IEEE Power & Energy Magazine - Grid Edge 2023 - 2
IEEE Power & Energy Magazine - Grid Edge 2023 - 3
IEEE Power & Energy Magazine - Grid Edge 2023 - 4
IEEE Power & Energy Magazine - Grid Edge 2023 - 5
IEEE Power & Energy Magazine - Grid Edge 2023 - 6
IEEE Power & Energy Magazine - Grid Edge 2023 - 7
IEEE Power & Energy Magazine - Grid Edge 2023 - 8
IEEE Power & Energy Magazine - Grid Edge 2023 - 9
IEEE Power & Energy Magazine - Grid Edge 2023 - 10
IEEE Power & Energy Magazine - Grid Edge 2023 - 11
IEEE Power & Energy Magazine - Grid Edge 2023 - 12
IEEE Power & Energy Magazine - Grid Edge 2023 - 13
IEEE Power & Energy Magazine - Grid Edge 2023 - 14
IEEE Power & Energy Magazine - Grid Edge 2023 - 15
IEEE Power & Energy Magazine - Grid Edge 2023 - 16
IEEE Power & Energy Magazine - Grid Edge 2023 - 17
IEEE Power & Energy Magazine - Grid Edge 2023 - 18
IEEE Power & Energy Magazine - Grid Edge 2023 - 19
IEEE Power & Energy Magazine - Grid Edge 2023 - 20
IEEE Power & Energy Magazine - Grid Edge 2023 - 21
IEEE Power & Energy Magazine - Grid Edge 2023 - 22
IEEE Power & Energy Magazine - Grid Edge 2023 - 23
IEEE Power & Energy Magazine - Grid Edge 2023 - 24
IEEE Power & Energy Magazine - Grid Edge 2023 - 25
IEEE Power & Energy Magazine - Grid Edge 2023 - 26
IEEE Power & Energy Magazine - Grid Edge 2023 - 27
IEEE Power & Energy Magazine - Grid Edge 2023 - 28
IEEE Power & Energy Magazine - Grid Edge 2023 - 29
IEEE Power & Energy Magazine - Grid Edge 2023 - 30
IEEE Power & Energy Magazine - Grid Edge 2023 - 31
IEEE Power & Energy Magazine - Grid Edge 2023 - 32
IEEE Power & Energy Magazine - Grid Edge 2023 - 33
IEEE Power & Energy Magazine - Grid Edge 2023 - 34
IEEE Power & Energy Magazine - Grid Edge 2023 - 35
IEEE Power & Energy Magazine - Grid Edge 2023 - 36
IEEE Power & Energy Magazine - Grid Edge 2023 - 37
IEEE Power & Energy Magazine - Grid Edge 2023 - 38
IEEE Power & Energy Magazine - Grid Edge 2023 - 39
IEEE Power & Energy Magazine - Grid Edge 2023 - 40
IEEE Power & Energy Magazine - Grid Edge 2023 - 41
IEEE Power & Energy Magazine - Grid Edge 2023 - 42
IEEE Power & Energy Magazine - Grid Edge 2023 - 43
IEEE Power & Energy Magazine - Grid Edge 2023 - 44
IEEE Power & Energy Magazine - Grid Edge 2023 - 45
IEEE Power & Energy Magazine - Grid Edge 2023 - 46
IEEE Power & Energy Magazine - Grid Edge 2023 - 47
IEEE Power & Energy Magazine - Grid Edge 2023 - 48
IEEE Power & Energy Magazine - Grid Edge 2023 - 49
IEEE Power & Energy Magazine - Grid Edge 2023 - 50
IEEE Power & Energy Magazine - Grid Edge 2023 - 51
IEEE Power & Energy Magazine - Grid Edge 2023 - 52
IEEE Power & Energy Magazine - Grid Edge 2023 - 53
IEEE Power & Energy Magazine - Grid Edge 2023 - 54
IEEE Power & Energy Magazine - Grid Edge 2023 - 55
IEEE Power & Energy Magazine - Grid Edge 2023 - 56
IEEE Power & Energy Magazine - Grid Edge 2023 - 57
IEEE Power & Energy Magazine - Grid Edge 2023 - 58
IEEE Power & Energy Magazine - Grid Edge 2023 - 59
IEEE Power & Energy Magazine - Grid Edge 2023 - 60
IEEE Power & Energy Magazine - Grid Edge 2023 - 61
IEEE Power & Energy Magazine - Grid Edge 2023 - 62
IEEE Power & Energy Magazine - Grid Edge 2023 - 63
IEEE Power & Energy Magazine - Grid Edge 2023 - 64
IEEE Power & Energy Magazine - Grid Edge 2023 - 65
IEEE Power & Energy Magazine - Grid Edge 2023 - 66
IEEE Power & Energy Magazine - Grid Edge 2023 - 67
IEEE Power & Energy Magazine - Grid Edge 2023 - 68
IEEE Power & Energy Magazine - Grid Edge 2023 - 69
IEEE Power & Energy Magazine - Grid Edge 2023 - 70
IEEE Power & Energy Magazine - Grid Edge 2023 - 71
IEEE Power & Energy Magazine - Grid Edge 2023 - 72
IEEE Power & Energy Magazine - Grid Edge 2023 - 73
IEEE Power & Energy Magazine - Grid Edge 2023 - 74
IEEE Power & Energy Magazine - Grid Edge 2023 - 75
IEEE Power & Energy Magazine - Grid Edge 2023 - 76
IEEE Power & Energy Magazine - Grid Edge 2023 - 77
IEEE Power & Energy Magazine - Grid Edge 2023 - 78
IEEE Power & Energy Magazine - Grid Edge 2023 - 79
IEEE Power & Energy Magazine - Grid Edge 2023 - 80
IEEE Power & Energy Magazine - Grid Edge 2023 - 81
IEEE Power & Energy Magazine - Grid Edge 2023 - 82
IEEE Power & Energy Magazine - Grid Edge 2023 - 83
IEEE Power & Energy Magazine - Grid Edge 2023 - 84
IEEE Power & Energy Magazine - Grid Edge 2023 - 85
IEEE Power & Energy Magazine - Grid Edge 2023 - 86
IEEE Power & Energy Magazine - Grid Edge 2023 - 87
IEEE Power & Energy Magazine - Grid Edge 2023 - 88
IEEE Power & Energy Magazine - Grid Edge 2023 - 89
IEEE Power & Energy Magazine - Grid Edge 2023 - 90
IEEE Power & Energy Magazine - Grid Edge 2023 - 91
IEEE Power & Energy Magazine - Grid Edge 2023 - 92
IEEE Power & Energy Magazine - Grid Edge 2023 - 93
IEEE Power & Energy Magazine - Grid Edge 2023 - 94
IEEE Power & Energy Magazine - Grid Edge 2023 - 95
IEEE Power & Energy Magazine - Grid Edge 2023 - 96
IEEE Power & Energy Magazine - Grid Edge 2023 - 97
IEEE Power & Energy Magazine - Grid Edge 2023 - 98
IEEE Power & Energy Magazine - Grid Edge 2023 - 99
IEEE Power & Energy Magazine - Grid Edge 2023 - 100
IEEE Power & Energy Magazine - Grid Edge 2023 - 101
IEEE Power & Energy Magazine - Grid Edge 2023 - 102
IEEE Power & Energy Magazine - Grid Edge 2023 - 103
IEEE Power & Energy Magazine - Grid Edge 2023 - 104
IEEE Power & Energy Magazine - Grid Edge 2023 - 105
IEEE Power & Energy Magazine - Grid Edge 2023 - 106
IEEE Power & Energy Magazine - Grid Edge 2023 - 107
IEEE Power & Energy Magazine - Grid Edge 2023 - 108
IEEE Power & Energy Magazine - Grid Edge 2023 - Cover3
IEEE Power & Energy Magazine - Grid Edge 2023 - Cover4
https://www.nxtbook.com/nxtbooks/pes/powerenergy_gridedge_2023
https://www.nxtbook.com/nxtbooks/pes/powerenergy_050622
https://www.nxtbook.com/nxtbooks/pes/powerenergy_030422
https://www.nxtbook.com/nxtbooks/pes/powerenergy_010222
https://www.nxtbook.com/nxtbooks/pes/powerenergy_111221
https://www.nxtbook.com/nxtbooks/pes/powerenergy_091021
https://www.nxtbook.com/nxtbooks/pes/powerenergy_070821
https://www.nxtbook.com/nxtbooks/pes/powerenergy_050621
https://www.nxtbook.com/nxtbooks/pes/powerenergy_030421
https://www.nxtbook.com/nxtbooks/pes/powerenergy_010221
https://www.nxtbook.com/nxtbooks/pes/powerenergy_111220
https://www.nxtbookmedia.com