ДСТУ EN 61643-11:2015 Пристрої захисту від імпульсних перенапруг низьковольтні. Частина 11. Пристрої захисту від імпульсних перенапруг, підключені до низьковольтних електромереж. Вимоги та методи випробування...

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EN 61643-11:2012

Low-voltage surge protective devices -
Part 11: Surge protective devices connected to low-voltage power systems -
Requirements and test methods

прийнято як національний стандарт
методом «підтвердження» за позначенням
 

ДСТУ EN 61643-11:2015
(EN 61643-11:2012, IDT)

Пристрої захисту від імпульсних перенапруг низьковольтні. Частина 11. Пристрої
захисту від імпульсних перенапруг, підключені до низьковольтних електромереж.
Вимоги та методи випробування

З наданням чинності від 2016-01-01

CONTENTS

INTRODUCTION

1 Scope

2 Normative references

3 Terms, definitions and abbreviations

3.1 Terms and definitions

3.2 Abbreviations

4 Service conditions

4.1 Frequency

4.2 Voltage

4.3 Air pressure and altitude

4.4 Temperatures

4.5 Humidity

5 Classification

5.1 Number of ports

5.1.1 One

5.1.2 Two

5.2 SPD design

5.2.1 Voltage switching

5.2.2 Voltage limiting

5.2.3 Combination

5.3 Class I, II and III tests

5.4 Location

5.4.1 Indoor

5.4.2 Outdoor

5.5 Accessibility

5.5.1 Accessible

5.5.2 Inaccessible

5.6 Mounting method

5.6.1 Fixed

5.6.2 Portable

5.7 Disconnectors (including overcurrent protection)

5.7.1 Location

5.7.2 Protection functions

5.8 Degree of protection provided by enclosures

5.9 Temperature and humidity range

5.9.1 Normal

5.9.2 Extended

5.10 Power system

5.10.1 AC between 47 Hz and 63 Hz

5.10.2 AC other than the range of 47 Hz to 63 Hz

5.11 Multipole SPD

5.12 SPD failure behaviour

5.12.1 open circuit (standard type SPD)

5.12.2 short-circuit (short-circuiting type SPD)

6 Preferred values for SPD

6.1 Preferred values of impulse discharge current I_imp for class I tests

6.2 Preferred values of nominal discharge current for class II tests I_n

6.3 Preferred values of open-circuit voltage for class III tests U_oc

6.4 Preferred values of voltage protection level U_p

6.5 Preferred values of r.m.s. maximum continuous operating voltage U_c

7 Requirements

7.1 General requirements

7.1.1 Identification

7.1.2 Marking

7.2 Electrical requirements

7.2.1 Protection against direct contact

7.2.2 Residual current I_PE

7.2.3 Voltage protection level U_p

7.2.4 Operating duty

7.2.5 Disconnectors and status indicators

7.2.6 Insulation resistance

7.2.7 Dielectric withstand

7.2.8 Behaviour under Temporary Overvoltages

7.3 Mechanical requirements

7.3.1 Mounting

7.3.2 Screws, current carrying parts and connections

7.3.3 External connections

7.3.4 Air clearances and creepage distances

7.3.5 Mechanical strength

7.4 Environmental and material requirements

7.4.1 Protection provided by enclosure (IP code)

7.4.2 Heat resistance

7.4.3 Fire resistance

7.4.4 Tracking resistance

7.4.5 Electromagnetic compatibility

7.5 Additional requirements for specific SPD designs

7.5.1 Two port SPDs and one port SPDs with separate input/output terminals

7.5.2 Environmental tests for outdoor SPDs

7.5.3 SPDs with separate isolated circuits

7.5.4 Short-circuiting type SPDs

7.6 Additional requirements as may be declared by the manufacturer

7.6.1 One-port and two-port SPDs

7.6.2 Two port SPDs only

8 Type tests

8.1 General testing procedures

8.1.1 Impulse discharge current used for class I additional duty test

8.1.2 Current impulse used for class I and class II residual voltage and operating duty tests

8.1.3 Voltage impulse used for class I and II sparkover tests

8.1.4 Combination wave used for class III tests

8.2 Indelibility of markings

8.3 Electrical tests

8.3.1 Protection against direct contact

8.3.2 Residual current I_PE

8.3.3 Measured limiting voltage

8.3.4 Operating duty test

8.3.5 Disconnectors and safety performance of overstressed SPDs

8.3.6 Insulation resistance

8.3.7 Dielectric withstand

8.3.8 Behaviour under Temporary Overvoltages (TOVs)

8.4 Mechanical tests

8.4.1 Reliability of screws, current-carrying parts and connections

8.4.2 Terminals for external conductors

8.4.3 Verification of air clearances and creepage distances

8.4.4 Mechanical strength

8.5 Environmental and material tests

8.5.1 Resistance to ingress of solid objects and to harmful ingress of water

8.5.2 Heat resistance

8.5.3 Ball pressure test

8.5.4 Resistance to abnormal heat and fire

8.5.5 Tracking resistance

8.6 Additional tests for specific SPD designs

8.6.1 Test for two-port SPDs and one-port SPDs with separate input/output terminals

8.6.2 Environmental tests for outdoor SPDs

8.6.3 SPDs with separate isolated circuits

8.6.4 Short-circuiting type SPDs

8.7 Additional tests for specific performance if declared by the manufacturer

8.7.1 Total discharge current test for multipole SPDs

8.7.2 Test to determine the voltage drop

8.7.3 Load-side surge withstand capability

8.7.4 Measurement of voltage rate of rise du/dt

9 Routine and acceptance tests

9.1 Routine tests

9.2 Acceptance tests

Annex A (normative) Reference test voltages for SPDs U_REF

Annex B (normative) TOV Ratings

Annex C (normative) Tests to determine the presence of a switching component and the magnitude of the follow current

Annex D (normative) Reduced test procedures

Annex E (informative) Alternative circuits for testing SPDs under TOVs caused by faults in the high (medium) voltage system

Annex F (informative) Environmental tests for outdoor SPDs

Annex G (normative) Temperature rise limits

Bibliography

Figure 1 – Metallic screen test set-up

Figure 2 – Example of a decoupling network for single-phase power

Figure 3 – Example of a decoupling network for three-phase power

Figure 4 – Alternate test for the measured limiting voltage

Figure 5 – Flow chart of testing to check the voltage protection level U_p

Figure 6 – Flow chart of the operating duty test

Figure 7 – Test set-up for operating duty test

Figure 8 – Operating duty test timing diagram for test classes I and II

Figure 9 – Additional duty test timing diagram for test class I

Figure 10 – Operating duty test timing diagram for test class III

Figure 11 – Test circuit for SPD with I_fi lower than the declared short-circuit rating

Figure 12 – Test circuit for SPD’s failure mode simulation

Figure 13 – Timing diagram for SPD’s failure mode simulation

Figure 14 – Example of a test circuit to perform the test under TOVs caused by faults in the low voltage system

Figure 15 – Timing diagram for the test under TOVs caused by faults in the low voltage system

Figure 16 – Example of circuit for testing SPDs for use in TT systems under TOVs caused by faults in high (medium) voltage system

Figure 17 – Timing diagram for use in testing SPDs under TOVs caused by faults in the high (medium) voltage system using circuit of Figure 16

Figure 18 – Test apparatus for impact test

Figure 19 – Striking element of the pendulum hammer

Figure 20 – Ball thrust tester

Figure 21 – Loading rod for ball thrust tester

Figure 22 – Examples for appropriate test circuits of the load side short-circuit test(s)

Figure E.1 – Examples of a three-phase and single-phase circuit for use in testing SPDs under TOVs caused by faults in the high (medium) voltage system

Table 1 – List of Abbreviations

Table 2 – Class I, II and III tests

Table 3 – Type test requirements for SPDs

Table 4 – Common pass criteria for type tests

Table 5 – Cross reference for pass criteria versus type tests

Table 6 – Preferred parameters for class I test

Table 7 – Tests to be performed to determine the measured limiting voltage

Table 8 – Prospective short-circuit current and power factor

Table 9 – Dielectric withstand

Table 10 – Screw thread diameters and applied torques

Table 11 – Cross-sections of copper conductors for screw-type or screwless terminals

Table 12 – Pulling forces (screw terminals)

Table 13 – Conductor dimensions

Table 14 – Pulling forces (screwless terminals)

Table 15 – Air clearances for SPDs

Table 16 – Creepage distances for SPDs

Table 17 – Relationship between material groups and classifications

Table 18 – Fall distances for impact requirements

Table 19 – Test conductors for rated load current test

Table 20 – Current factor k for overload behaviour

Table 21 – Tolerances for proportional surge currents

Table A.1 – Reference test voltage values

Table B.1 – TOV test values for systems complying with IEC 60364 series .

Table B.2 – TOV test parameters for North American systems

Table B.3 – TOV test parameters for Japanese systems

Table D.1 – Reduced test procedure for SPDs complying with IEC 61643-1:2005

Table G.1 – Temperature-rise limits