SIST EN 50549-1:2019/oprA1:2023

SLOVENSKI STANDARD
SIST EN 50549-1:2019/oprA1:2023
01-junij-2023
Zahteve za vzporedno vezavo generatorskih postrojev z razdelilnim omrežjem - 1.
del: Vezava z nizkonapetostnim razdelilnim omrežjem - Generatorski postroji do
vključno tipa B - Dopolnilo A1
Requirements for generating plants to be connected in parallel with distribution networks
- Part 1: Connection to a LV distribution network - Generating plants up to and including
Type B
Ta slovenski standard je istoveten z: EN 50549-1:2019/prA1:2023
ICS:
29.160.20 Generatorji Generators
29.240.01 Omrežja za prenos in Power transmission and
distribucijo električne energije distribution networks in
na splošno general
SIST EN 50549-1:2019/oprA1:2023 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN 50549-1:2019/oprA1:2023

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SIST EN 50549-1:2019/oprA1:2023


EUROPEAN STANDARD DRAFT
EN 50549-1:2019
NORME EUROPÉENNE

EUROPÄISCHE NORM
prA1
May 2023
ICS 29.160.20 -
English Version
Requirements for generating plants to be connected in parallel
with distribution networks - Part 1: Connection to a LV
distribution network - Generating plants up to and including
Type B
To be completed To be completed
This draft amendment prA1, if approved, will modify the European Standard EN 50549-1:2019; it is submitted to CENELEC members for
enquiry.
Deadline for CENELEC: 2023-08-11.

It has been drawn up by CLC/TC 8X.

If this draft becomes an amendment, CENELEC members are bound to comply with the CEN/CENELEC Internal Regulations which
stipulate the conditions for giving this amendment the status of a national standard without any alteration.

This draft amendment was established by CENELEC in three official versions (English, French, German).
A version in any other language made by translation under the responsibility of a CENELEC member into its own language and notified to
the CEN-CENELEC Management Centre has the same status as the official versions.

CENELEC members are the national electrotechnical committees of Austria, Belgium, Bulgaria, Croatia, Cyprus, the Czech Republic,
Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, the
Netherlands, Norway, Poland, Portugal, Republic of North Macedonia, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland,
Türkiye and the United Kingdom.

Recipients of this draft are invited to submit, with their comments, notification of any relevant patent rights of which they are aware and to
provide supporting documentation.

Warning : This document is not a European Standard. It is distributed for review and comments. It is subject to change without notice and
shall not be referred to as a European Standard.



European Committee for Electrotechnical Standardization
Comité Européen de Normalisation Electrotechnique
Europäisches Komitee für Elektrotechnische Normung
CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels
© 2023 CENELEC All rights of exploitation in any form and by any means reserved worldwide for CENELEC Members.
Project: 73643 Ref. No. EN 50549-1:2019/prA1:2023 E

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SIST EN 50549-1:2019/oprA1:2023
EN 50549-1:2019/prA1:2023 (E)
9 Contents Page
10 European foreword . 3
11 1 Modification to Introduction . 4
12 2 Modification to Clause 2, “Normative references” . 4
13 3 Modification to Clause 3, “Terms and definitions” . 4
14 4 Modification to Clause 4, “Requirements on generating plants” . 6
15 5 Modification to Annex C, “Parameter Table” .10
16 6 Modification to Annex D, “List of national requirements applicable for generating plants”
17 .11
18 7 Modification to Annex F, “Examples of protection strategies” .11
2

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SIST EN 50549-1:2019/oprA1:2023
EN 50549-1:2019/prA1:2023 (E)
19 European foreword
20 This document EN 50549-1:2019/prA1:2023 has been prepared by TC 8X “System aspects of electrical energy
21 supply”.
22 This document is currently submitted to the Enquiry.
23 The following dates are proposed:
• latest date by which the existence of this (doa) dor + 6 months
document has to be announced at national
level
• latest date by which this document has to be (dop) dor + 12 months
implemented at national level by publication of
an identical national standard or by
endorsement
• latest date by which the national standards (dow) dor + 36 months
conflicting with this document have to be (to be confirmed or
withdrawn modified when voting)
24 This document will amend EN 50549-1:2019.
25 This amendment includes the following significant technical changes:
26 — Introduction of a phase jump immunity requirement.
27 — Harmonizing the ROCOF immunity requirement for synchronous and non-synchronous generating
28 technology.
29 — Modifying FRT for type A from recommendation to requirement.
30 — Providing additional detail for EESS in case of overfrequency.
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EN 50549-1:2019/prA1:2023 (E)
31 1 Modification to Introduction
32 Replace item 8. with the following:
33 “8. Implementation of UVRT and LFSM-U to avoid legal conflict with RfG
34 Under Voltage Ride Through (UVRT) requirements are defined in RfG for modules type B, type C and type D.
35 There is no mentioning of this topic for type A modules.
36 Nevertheless, UVRT is seen as an important requirement in some member states even for small generation
37 modules like type A.
38 NOTE At the time of writing, LVRT requirements for type A modules have been implemented in the following countries:
39 Austria, Czech Republic, Germany, Portugal (for PGM of 15 kW and higher), Switzerland.
40 From a legal point of view there are two contradicting opinions on whether it is allowed or forbidden to require
41 UVRT for type A modules.
42 — Opinion 1: It can be required because the topic is not dealt with for type A modules.
43 — Option 2: It cannot be required because the topic UVRT is dealt within the RfG. Not mentioning UVRT for
44 type A in RfG therefore means that it cannot be required for type A modules.
45 TC8X WG03 adopts the view of ACER as expressed in “ACER Monitoring of the Implementation of the Grid
46 Connection Network Codes” 11 November 2021 Item 3.3.4 #D where it states the German UVRT requirement
47 for Type A as compliant with NC RfG.
48 This same explanation can be applied to the requirements regarding Limited Frequency Sensitive Mode -
49 Underfrequency (LFSM-U). In RfG, this LFSM-U is solely defined for type C and type D modules. In EN 50549,
50 LFSM-U is defined as a recommendation (should) for generating modules of type A and type B. The sole
51 exception is electrical energy storage systems having a requirement (shall). These systems are currently not
52 within the scope of the RfG.”
53 2 Modification to Clause 2, “Normative references”
54 Add the following reference:
55 EN 50549-10, Requirements for generating plants to be connected in parallel with distribution networks - Part
56 10: Tests for conformity assessment of generating units
57 Delete the reference EN 60255-127.
58 3 Modification to Clause 3, “Terms and definitions”
59 Add the following note to entry to 3.2.10:
60 “
61 Note 3 to entry: Electric vehicle charging stations intended to feed power back to the grid are considered an EESS while
62 a vehicle is connected.”
63 Add the following note to entry to 3.2.11:
64 “
65 Note 2 to entry: Electric vehicle charging stations intended to feed power back to the grid are considered a EES while a
66 vehicle is connected.”
67 Add the following term entries:
68 “
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SIST EN 50549-1:2019/oprA1:2023
EN 50549-1:2019/prA1:2023 (E)
69 3.3.10
70 apparent power
71 product of the rms voltage U between the terminals of a two-terminal element or two-terminal circuit and the
72 rms electric current I in the element or circuit
73 S=UI
74 Note 1 to entry: Under sinusoidal conditions, the apparent power is the modulus of the complex power , thus .
S SS=
75 Note 2 to entry: The coherent SI unit for apparent power is voltampere, VA.
76 [SOURCE: IEV 131-11-41]
77 3.3.11
78 reactive power
79 for a linear two-terminal element or two-terminal circuit, under sinusoidal conditions, quantity equal to the mean
80 value of the product of the instantaneous voltage u and the instantaneous current i' which is equal to i but
81 leading it by π / 2 :
T
1
82 Q ui''uidt
∫
0
T
83 where T denotes half the period of u , Q being equivalent to the product of the apparent power S and the
84 sine of the displacement angle
ϕ
85 QS= sinϕ
86 Note 1 to entry: The reactive power is the imaginary part of the complex power , thus . Its absolute value is
S Q=ImS
87 equal to the non-active power, thus QQ= .
∼
88 Note 2 to entry: The coherent SI unit for reactive power is voltampere, VA. The special name var and its symbol var are also
89 used.
90 [SOURCE: IEV 131-11-44]
91 3.4.9
92 phase
93 instantaneous phase
94 ϑ
95 argument of the cosine function in the representation of a sinusoidal quantity
96 Note 1 to entry: The term “instantaneous phase” is only used when the independent variable is time.
ˆ
97 Note 2 to entry: For the quantity a(t) = Atcos ω +ϑ , the phase is ωt+ϑ .
( )
0 0
98 [SOURCE: IEV 103-07-04]
99 3.4.10
100 instantaneous frequency
101 first derivative of instantaneous phase
5
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SIST EN 50549-1:2019/oprA1:2023
EN 50549-1:2019/prA1:2023 (E)
102 3.4.11
103 rate of change of frequency
104 ROCOF
105 first derivative of instantaneous frequency or second derivative of instantaneous phase
106 3.4.12
107 phase jump
108 abrupt change in the phase of the voltage of an AC electrical network
109 “
110 4 Modification to Clause 4, “Requirements on generating plants”
111 4.1 Modification to subclause 4.1, “General”
112 Add the following at the end of the subclause:
113 “EN 50549-10 provides technical guidance for tests on generating units and interface protection to evaluate
114 their electrical characteristics. EN 50549-10 shall be applied to evaluate the characteristics of generating units
115 and interface protection used in generating plants relating to the requirements of this Standard.
116 Electrical characteristics may alternatively be evaluated according to standards other than EN 50549-10, if the
117 following prerequisites are fulfilled:
118 — The alternative verification procedure covers all required technical aspects and characteristic quantities
119 stipulated in EN 50549-1 and EN 50549-2, respectively.
120 — The alternative verification procedure shall not be less stringent or technically less demanding than the
121 correspondent verification procedure in EN 50549-10.
122 — The alternative verification procedure leads to results of at least equivalent confidence level as
123 EN 50549-10.
124 — The equivalent or higher confidence level of the alternative verification procedure shall be confirmed by the
125 entity stating compliance based upon these tests.
126 — The entity stating compliance based upon these tests shall have sufficient expertise in both EN 50549-10
127 and the applied standard.
128 NOTE This also applies for a partial application of another standard only for specific functions or operational
129 capabilities.”
130 4.2 Modification to subclause 4.5, “Immunity to disturbances”
131 4.2.1 Modification to subclause 4.5.1, “General”
132 Add the following at the end of the subclause:
133 “The described immunity requirements are independent of the interface protection settings. Disconnection
134 settings of the interface protection relay always overrule technical capabilities. So, whether the generating plant
135 will stay connected or not will also depend upon those settings.”
136 4.2.2 Modification to subclause 4.5.2, “Rate of change of frequency (ROCOF) immunity”
137 Replace the content of the subclause with the following:
138 “ROCOF immunity of a power generating plant means that the generating modules in this plant stay connected
139 with the distribution network and are able to operate when the frequency on the distribution network changes
140 with a specified ROCOF. The generating units and all elements in the generating plant that might cause their
141 disconnection or impact their behaviour shall have the same level of immunity.
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EN 50549-1:2019/prA1:2023 (E)
142 The generating modules in a generating plant shall have ROCOF immunity to ROCOF equal or exceeding the
143 value specified by the responsible party. If no ROCOF immunity value is specified, at least 2 Hz/s shall apply.
144 The ROCOF immunity is defined with a sliding measurement window of 500 ms.
145 NOTE 1 For control action based on frequency measurement shorter measurement periods are expected to be
146 necessary.
147 NOTE 2 For small isolated distribution networks (typically on islands) higher ROCOF immunity values might be required.”
148 4.2.3 Modification to subclause 4.5.3, “Under-voltage ride through (UVRT)”
149 4.2.3.1 Modification to subclause 4.5.3.1, “General”
150 Replace the content of the subclause with the following:
151 “Generating modules shall comply with the requirements of 4.5.3.2 and 4.5.3.3.
152 Exempted from this requirement are small generating units below 50 kW of the following generation
153 technologies: CHP, fuel cell, rotating machinery, hydro.
154 NOTE 1 The power threshold of this exemption is expected to be reduced in future or the exception might be deleted
155 completely especially once the installed capacity becomes relevant for the grid stability.
156 The requirements apply to all kinds of faults (1ph, 2ph and 3ph).
157 NOTE 2 A more distinctive differentiation for 1ph, 2ph and 3ph faults is under consideration.
158 NOTE 3 The FRT curves in Figure 6, Figure 7 and Figure 8 describe the minimum requirements f
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