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IEEE C62.36-2016

IEEE C62.36-2016

$90.46

IEEE Standard Test Methods for Surge Protectors and Protective Circuits Used in Information and Communications Technology (ICT) Circuits, and Smart Grid Data Circuits

Published By Publication Date Number of Pages
IEEE 2016 150
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Revision Standard – Active. Surge protectors for application on multiconductor balanced or unbalanced information and communications technology (ICT) circuits and smart grid data circuits are addressed in this standard. These surge protectors are designed to limit voltage surges, current surges, or both. The surge protectors covered are generally multiple-component series or parallel combinations of linear or nonlinear elements, packaged or organized for the purpose of limiting voltage, current, or both. The methods of testing and criteria (where appropriate) for the characteristics and ratings of surge protectors used in ICT circuits and smart grid data circuits are also described in this standard. Packaged single gas tube, air gap, varistor, or avalanche junction surge-protective components are not covered by this standard, but rather are covered by IEEE Std C62.31™, IEEE Std C62.32™, IEEE Std C62.33™, and IEEE Std C62.35™, respectively. Specifically excluded from this standard are test methods for low-voltage power circuit applications. For protection of wire-line communication facilities under the specialized conditions found at power stations, consult IEEE Std 487™.

PDF Catalog

PDF Pages PDF Title
1 IEEE Std C62.36™-2016 Front cover
2 Title page
4 Important Notices and Disclaimers Concerning IEEE Standards Documents
9 Contents
11 IMPORTANT NOTICE
1. Scope
12 2. Normative references
3. Definitions, acronyms, and abbreviations
3.1 Definitions
13 3.2 Acronyms and abbreviations
14 4. Service conditions
4.1 Normal service conditions
4.1.1 Environmental conditions
15 4.1.2 Physical properties
4.1.3 System conditions
4.1.4 Surge rating of the surge protector under system conditions
4.2 Unusual service conditions
4.2.1 Environmental conditions
16 4.2.2 Physical conditions
4.2.3 System conditions
4.3 Radiation
5. Basic configurations
18 6. Standard design test procedure
6.1 Standard design test criteria
6.2 Statistical procedures
6.3 Test conditions
6.4 Test measurements
7. Surge protector characteristics
7.1 General
19 7.2 DC series resistance
7.2.1 Background
7.2.2 Purpose
7.2.3 Equipment
7.2.4 Protector states subject to test
7.2.5 Procedures
7.2.6 Alternative methods
7.2.7 Suggested test data
20 7.2.8 Requirement
7.2.9 Comment
7.3 Capacitance
7.3.1 Background
7.3.1.1 General
21 7.3.1.2 Voltage-dependent capacitance
22 7.3.1.3 Separating out the individual capacitive components
23 7.3.2 Equipment
7.3.3 Equipment states subject to test
24 7.3.4 Procedures
7.3.5 Alternative methods
7.3.6 Suggested test data
7.3.7 Requirements
7.3.8 Comments
25 7.4 Inductance
7.4.1 Background
7.4.2 Purpose
7.4.3 Equipment
7.4.4 Protector states subject to test
26 7.4.5 Procedures
7.4.6 Alternative methods
7.4.7 Suggested test data
27 7.4.8 Requirements
7.4.9 Comment
7.5 Insulation resistance (IR) test
7.5.1 Background
28 7.5.2 Purpose
7.5.3 Equipment
7.5.4 Protector states subject to test
7.5.5 Procedures
29 7.5.6 Alternative methods
7.5.7 Suggested test data
7.5.8 Requirements
7.5.9 Comment
7.6 Standby current test
7.6.1 Background
31 7.6.2 Purpose
7.6.3 Equipment
7.6.4 Protector states subject to test
7.6.5 Procedures
32 7.6.6 Alternative methods
7.6.7 Suggested test data
7.6.8 Requirements
7.6.9 Comment
33 7.7 DC ringing current
7.7.1 Background
7.7.2 Purpose
7.7.3 Equipment
7.7.4 Protector states subject to test
34 7.7.5 Procedures
7.7.6 Alternative generators
35 7.7.7 Suggested test data
7.7.8 Requirements
7.7.9 Comments
7.8 Distortion
7.8.1 Background
36 7.8.2 Purpose
7.8.3 Equipment
7.8.4 Protector states subject to test
37 7.8.5 Procedures
39 7.8.6 Alternative methods
40 7.8.7 Suggested test data
7.8.8 Requirements
7.8.9 Comments
7.9 Transmission properties: insertion loss, return loss, phase shift
47 7.10 Longitudinal conversion transfer loss (LCTL)
50 7.11 Voltage reset [electronic current limiters (ECLs)]
53 7.12 Impulse reset
58 7.13 Transition current test for thermally activated components
61 7.14 Time-to-trip test for thermally activated components
64 7.14.6.1 Equipment
7.14.6.2 Procedures
66 7.15 Transverse surge generation
70 7.16 DC-limiting voltage
74 7.16.7.1 Equipment
7.16.7.2 Procedures
75 7.17 Impulse-limiting voltage
79 7.18 In-line surge protector: protected port surge current let-through
81 7.19 In-line surge protector: surge series resistance
84 7.20 In-line surge protector: protected port ground potential rise (GPR)
86 7.20.5 Differential GPR test levels
87 7.21 In-line surge protector: protected port ground lead inductive voltage spike
88 7.21.5.1 Figure 42 circuit values
89 7.21.5.2 Procedures
90 8. Preferred surge protector ratings under specified conditioning
8.1 Surge protector ratings under environmental cycling with impulse surges
94 8.2 Surge protector ratings under environmental cycling with ac exposure
96 8.2.8 Requirement
98 8.3 Surge protector ratings under ac life (durability)
100 8.4 Surge protector ratings under impulse life (durability)
104 8.5 Surge protector ratings under maximum single-impulse discharge
106 9. Failure modes
107 Annex A (informative) Examples of internal arrangements of sur
110 Annex B (informative) Test measurement techniques
B.1 Introduction
B.2 Oscilloscopes
111 B.3 Voltage measurements
112 B.4 Current measurements
113 Annex C (informative) Impulse generators
C.1 Introduction
C.2 Types of impulse generator
C.3 Impulse generator parameters
116 C.4 Impulse generators typically used for surge protector testing
118 C.5 Impulse generator circuits
122 C.6 Combination wave generators
124 C.7 Expanding single-output generators to multiple output
127 C.8 Generator variants
132 Annex D (informative) Cable discharge events
D.1 Background
D.2 Event characteristics
133 D.3 Test methods
135 Annex E (informative)
GDT-based surge protector oscillation test
E.1 Background
136 E.2 Purpose
E.3 Equipment
E.4 Equipment states subject to test
137 E.5 Procedures
E.6 Alternative methods
138 E.7 Suggested data
139 E.8 Comments
140 Annex F (informative)Multiport surge protector
F.1 Introduction
F.2 Individual service protection
141 F.3 Standards that address multiport coupling
143 Annex G (informative) Comments on characteristics and ratings
144 Annex H (informative) Signal transformers voltage-time product
H.1 Background
H.2 Purpose
H.3 Equipment
H.4 Protector states subject to test
H.5 Procedures
145 H.6 Alternative method
H.7 Suggested test data
H.8 Requirement
146 H.9 Comments
147 Annex I (informative) Bibliography
150 Back cover

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IEEE C62.36-2016
$90.46