16011089.001 503792 CB Certification

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Page 2 of 73

Copy of marking plate(s):
With Euro-plug:

With BS plug:

The GS mark, T-mark, CE mark, indoor use and class II symbol are moulded on enclosure.
With Australian plug:

With Indian plug:

These are representative labels, the others are identical to them except the model number and input voltage
rang and output ratings as listed in the model list on page 5.
Summary of testing:
1. The tested samples comply with the requirements of this standard.
2. Compliance with the National requirements of countries which are same as national differences countries
as given in CB Bulletin 112A.
3. The models DSA-5W-05 FEU 050100, DSA-5W-12 FEU 082061 and DSA-5W-12 FEU 120042 have
been selected for test, and unless otherwise specified, the model DSA-5W-12 FEU 120042 was tested.
4. The models are in compliance with the requirements of subclause 2.5 (limited power source).

TRF No.:IECEN60950_1B

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Page 3 of 73

Particulars: test item vs. test requirements
Equipment mobility .......................................: Direct plug-in equipment
Operating condition .......................................: Continuous
Mains supply tolerance (%) ...........................: + 10% / - 10% (as request by client)
Tested for IT power systems ........................: Yes, Norway
IT testing, phase-phase voltage (V) .............: 230 (only for Norway)
Class of equipment .......................................: Class II
Mass of equipment (kg).................................: Approx. 0.08kg
Protection against ingress of water ..............: IPX0
Test case verdicts
Test case does not apply to the test object ..: N/A
Test item does meet the requirement ..........: P(ass)
Test item does not meet the requirement ....: F(ail)
Testing
Date of receipt of test item ...........................: 25 Oct, 2007
Date(s) of performance of test .....................: 25 Oct, 2007 – 30 Oct, 2007
General remarks
”This report is not valid as a CB Test Report unless appended by an approved CB Testing
Laboratory and appended to a CB Test Certificate issued by an NCB in accordance with IECEE 02”.
The test result presented in this report relate only to the object(s) tested.
This report shall not be reproduced, except in full, without the written approval of the Issuing testing
laboratory.
”(see Enclosure #)" refers to additional information appended to the report.
"(see appended table)" refers to a table appended to the report.
Throughout this report a point is used as the decimal separator.
Comments:
Summary of compliance with National Differences (for explanation of codes see below):
AT, AU, BE, CH, DE, DK, FI, FR, GB, GR, HU, IL, IN, IT, KE, MY, NL, NO, PL, SE, SG, SI, SK
AT=Austria, AU=Australia, BE=Belgium, CH=Switzerland, DE=Germany, DK=Denmark, FI=Finland,
FR=France, GB=United Kingdom, GR=Greece, HU=Hungary, IL=Israel, IN=India, IT=Italy, KE=Kenya,
MY=Malaysia, NL=The Netherlands, NO=Norway, PL=Poland, SE=Sweden, SG=Singapore, SI=Slovenia,
SK=Slovakia
All national differences of EU group considered according to EN 60950-1:2001, Annex ZA, Annex ZB and
Annex ZC on pages 28–37; National differences of Australia considered according to AS/NZS 60950.1-2003
on pages 53–59; EN 60950-1/A11 have been added to original TRF, see page 28-37.
The dimension of European plug checked according to EN 50075 (see appended table on page 60), the
British plug was evaluated according to BS1363 (see appended table on pages 61-62), the Australian plug
was evaluated according to AS/NZS 3112 (see appended table on pages 63-72). The Indian plug was
evaluated according to BS 4573 (see appended table on pages 73)
Factories:
1) Dee Van Electronics (Shenzhen) Co., Ltd.
th
The 5 Industrial District, Gongming, Bao An District, Shenzhen, Guangdong 518106, P.R. China
2) Dee Van Electronics (Longchuan) Co., Ltd.
Meichun Industrial District, Longchuan Country, Heyuan, Guangdong 517300, P.R. China
3) Dee Van Technology (Longchuan) Co., Ltd.
Meichun Industrial District, Longchuan Country, Heyuan, Guangdong 517300, P.R. China

TRF No.:IECEN60950_1B

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Page 4 of 73

General product information:
Brief description of the test sample:
1. The equipment models DSA-5W-a Ab xy, DSA-5W-a Fb xy are Switching Adapter (direct plug-in type)
used for DC supply of IT or office equipment.
2. The power supply’s top enclosure is secured to bottom enclosure by ultrasonic welding.
3. The test items are pre-production samples without serial numbers.
4. The model reference is DSA-5W-a Ab xy, DSA-5W-a Fb xy, ‘a’ represents output voltage range, ‘b’
represents used plug type, ‘x’ represents the output voltage and ‘y’ represents the output current,
details see model list on page 5;
5. The plug pin holder of European plug and Indian plug were fixed into the enclosure of plug portion by a
screw. The pin parts of British plug and Australian plug were moulded into the enclosure of plug portion.
It is impossible to remain in the mains socket-outlet after removal of the adapter, details see photo
document.
6. The maximum ambient temperature is 40°C.
Difference between models:
1. The models DSA-5W-a Ab xy are identical to models DSA-5W-a Fb xy except for the model name and
input voltage range;
2. Transformer: The adaptors with different output voltage have different secondary winding of transformer,
details see model list in page 5;
3. R10, R11, R12, R13, R15, R17, C7, C9, D8, Z1, Z2, Z3: The parameters of these components depend
on output power and output voltage.

TRF No.:IECEN60950_1B

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Page 5 of 73

Model list:
DSA-5W-a Ab xy; DSA-5W-a Fb xy:

MODEL

DSA-5W-05 Ab xy

DSA-5W-12 Ab xy

DSA-5W-05 Fb xy

DSA-5W-12 Fb xy

INPUT
V, A
200–240VAC,
50/60Hz, 0.2A

100–240VAC,
50/60Hz, 0.2A

OUTPUT

T1 sec winding

V dc

Max. A

Max. W

5.0 – 8.1

1.00

0.35mmx14Ts

8.2-12.0

0.61

0.20mmx18Ts

5.0 – 8.1

1.00

0.35mmx14Ts

8.2-12.0

0.61

0.20mmx18Ts

Note:
’a’ can be 05, 12;
‘b’ can be ‘EU’, ‘UK’, ‘US’, ‘CH’, ‘AU’, ‘KA’, ‘JP’ or ‘IN’, EU means European plug used, UK means British
plug used, US means American or Japanese plug used, CH means Chinese plug used, AU means
Australian plug used, KA means Korean plug used, JP means Japanese plug used, IN means Indian plug
used;
‘x’ is 3 digit number which represents the output voltage in Volt after dividing by 10, from 5.0V to 12.0V in
step of 0.1V, for example, 090 represents the output voltage is 9.0 V, 120 represents the output voltage is
12.0V;
‘y’ is 3 digit number which represents the output current in Ampere after dividing by 100 which is up to 1.0A
in step of 0.01A, for example, 041 represents the output current is 0.41A, 100 represents the output current
is 1.00A.
By multiplication of output voltage and output current, the type designations are limited through the
max. output power.
Only the European plug, British plug, Australian plug and Indian were considered in this report. Other types
of plug should be evaluated during national approval.

TRF No.:IECEN60950_1B

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Page 6 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

GENERAL

1.5

Components

1.5.1

General

Components which were found
to affect safety aspects comply
with the requirements of this
standard or within the safety
aspects of the relevant IEC
component standards.

Comply with IEC 60950 or relevant component
standard

(see appended table 1.5.1)

1.5.2

Evaluation and testing of components

Components which are certified
to IEC and /or national
standards are used correctly
within their ratings.
Components not covered by
IEC standards are tested under
the conditions present in the
equipment.

1.5.3

Thermal controls

No thermal controls provided.

N/A

1.5.4

Transformers

Transformer used are suitable
for their intended application
and comply with the relevant
requirements of the standard
and particularly Annex C.

1.5.5

Interconnecting cables

Interconnection o/p cable to
other device is carrying only
SELV on an energy level below
240 VA.

→ Except for the insulation
material, there are no further
requirements for the o/p
interconnection cable.
1.5.6

Capacitors in primary circuits ...............................: No such capacitor used.

1.5.7

Double insulation or reinforced insulation bridged
by components

1.5.7.1

General

1.5.7.2

Bridging capacitors

Between primary side and
secondary: Y1-capacitor (CY1)
according to IEC 60384-14.

1.5.7.3

Bridging resistors

No such resistor used.

1.5.7.4

Accessible parts

See clause 2.4

1.5.8

Components in equipment for IT power systems

No such component

1.6

Power interface

1.6.1

AC power distribution systems

TRF No.:IECEN60950_1B

See below.

N/A
P
P

N/A
P

IT power system for Norway
only, TN power system for
others

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Page 7 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

1.6.2

Input current

Highest load according to
1.2.2.1 for this equipment is the
operation with the max.
specified DC-load.

Verdict
P

Results see appended table
1.6.3

Voltage limit of hand-held equipment

Not hand-held equipment.

N/A

1.6.4

Neutral conductor

Class II equipment without earth
connection.

N/A

1.7

Marking and instructions

1.7.1

Power rating

P
See below.

Rated voltage(s) or voltage range(s) (V) .............: AC100-240V for DSA-5W-a Fb
xy;
AC200-240V for DSA-5W-a Ab
xy
Symbol for nature of supply, for d.c. only .............: Mains from AC source

N/A

Rated frequency or rated frequency range (Hz) ..: 50/60Hz

Rated current (mA or A) ......................................: 0.2A

Manufacturer’s name or trademark or identification Not shown / trademark of DVE
mark .....................................................................:

Type/model or type reference...............................: DSA-5W-a Ab xy;
DSA-5W-a Fb xy

Symbol for Class II equipment only .....................: Double square symbol
provided.

Other symbols ......................................................: Additional symbols or marking
does not give rise to
misunderstanding.

Certification marks ...............................................: Refer to the copy of the label
drawings for details.

1.7.2

Safety instructions

"User'
s Manual" provided that
contains information regarding
the maximum ambient
temperature.

1.7.3

Short duty cycles

Equipment is designed for
continuous operation.

1.7.4

Supply voltage adjustment ...................................: No voltage selector.

N/A

Methods and means of adjustment; reference to
installation instructions .........................................:

N/A

1.7.5

Power outlets on the equipment ..........................: No power outlets provided.

N/A

1.7.6

Fuse identification (marking, special fusing
Fusing resistor used, marking
characteristics, cross-reference) .........................: adjacent to the fusing resistor
on PCB as:

N/A

RF1 4.7ohm 1W
1.7.7

Wiring terminals

TRF No.:IECEN60950_1B

See below.

N/A
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Page 8 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

1.7.7.1

Protective earthing and bonding terminals ..........: Class II equipment without earth
connection.

N/A

1.7.7.2

Terminal for a.c. mains supply conductors

Direct plug-in equipment.

N/A

1.7.7.3

Terminals for d.c. mains supply conductors

No d.c. mains supply.

N/A

1.7.8

Controls and indicators

No safety related switches or
indicators.

N/A

1.7.8.1

Identification, location and marking .....................:

N/A

1.7.8.2

Colours ...............................................................:

N/A

1.7.8.3

Symbols according to IEC 60417 .........................:

N/A

1.7.8.4

Markings using figures ........................................:

N/A

1.7.9

Isolation of multiple power sources .....................: Only one supply from the
mains.

N/A

1.7.10

IT power distribution systems

Only for Norway

1.7.11

Thermostats and other regulating devices

No such device.

N/A

1.7.12

Language(s) .........................................................: Installation instruction in
English and German.



Versions in other languages
have to be provided during the
corresponding national
approvals.
1.7.13

Durability

The label was subjected to the
permanence of marking test.
The label was rubbed with cloth
soaked with water for 15 sec.
And then again for 15 sec. With
the cloth soaked with
petroleum spirit.
After this test there was no
damage to the label. The
marking on the label did not
fade. There was no curling nor
lifting of the label edge.

1.7.14

Removable parts

No removable part.

N/A

1.7.15

Replaceable batteries

No battery provided.

N/A

Language(s)..........................................................:



1.7.16

Operator access with a tool ..................................: No operator accessible area
that needs to be accessed by
the use of a tool.

N/A

1.7.17

Equipment for restricted access locations ............: Not limited for use in restricted
access locations.

N/A

PROTECTION FROM HAZARDS

2.1

Protection from electric shock and energy hazards

TRF No.:IECEN60950_1B

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Page 9 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

2.1.1

Protection in operator access areas

No access with test finger and
test pin to any parts with only
basic insulation to ELV or
hazardous voltage.

2.1.1.1

Access to energized parts

See above.

Test by inspection ................................................: See above.

Test with test finger ..............................................: See above.

Test with test pin ..................................................: See above.

Test with test probe .............................................: No TNV.

N/A

2.1.1.2

Battery compartments .........................................: No battery compartment.

N/A

2.1.1.3

Access to ELV wiring

N/A

No ELV wiring in operator
accessible area.

Working voltage (Vpeak or Vrms); minimum
distance (mm) through insulation



2.1.1.4

Access to hazardous voltage circuit wiring

2.1.1.5

Energy hazards ....................................................: Energy does not exceed 240VA
between any two points in
accessible parts (o/p connector
of secondary circuit). Results
see appended table 2.1.1.5. No
energy hazard in operator
access area.

2.1.1.6

Manual controls

No manual controls.

N/A

2.1.1.7

Discharge of capacitors in equipment

No capacitor provided between
line and neutral.

N/A

No hazardous voltage wiring in
operator accessible area.

Time-constant (s); measured voltage (V) .............:

N/A
P



2.1.2

Protection in service access areas

No operator accessible area
that needs to be accessed by
the use of a tool.

N/A

2.1.3

Protection in restricted access locations

Not limited for use in restricted
access locations.

N/A

2.2

SELV circuits

2.2.1

General requirements

2.2.2

Voltages under normal conditions (V) ..................: Between any conductor of the
SELV circuits 42.4 V peak or
60 V d.c. are not exceeded.

P
The secondary circuits were
tested as SELV. See 2.2.1 to
2.2.4.

See appended table 2.2.2.

TRF No.:IECEN60950_1B

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Page 10 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

2.2.3

Voltages under fault conditions (V).......................: Single fault did not cause
excessive voltage in accessible
SELV circuits. Limits of 71V
peak and 120V d.c. were not
exceeded within 0.2 seconds
and limits 42.4V peak and 60V
d.c. were not exceeded for
longer than 0.2 seconds.

2.2.3.1

Separation by double insulation or reinforced
insulation (method 1)

2.2.3.2

Separation by earthed screen (method 2)

N/A

2.2.3.3

Protection by earthing of the SELV circuit
(method 3)

N/A

2.2.4

Connection of SELV circuits to other circuits........: See 2.2.2 and 2.2.3.

2.3

TNV circuits

2.3.1

Limits

2.3.2

2.3.3

Result – Remark

Double or reinforced for the
highest working voltage across
a particular insulation is
provided.

P
N/A

No TNV.

N/A

Type of TNV circuits .............................................:



Separation from other circuits and from accessible
parts

N/A

Insulation employed..............................................:



Separation from hazardous voltages

N/A

Insulation employed..............................................:
2.3.4

Verdict



Connection of TNV circuits to other circuits

N/A

Insulation employed..............................................:



2.3.5

Test for operating voltages generated externally

2.4

Limited current circuits

2.4.1

General requirements

2.4.2

Limit values

Frequency (Hz) .....................................................: (see appended table)



Measured current (mA).........................................: (see appended table)



Measured voltage (V) ...........................................: (see appended table)



Measured capacitance (µF) ..................................: 2200pF



N/A

2.4.3

Connection of limited current circuits to other
circuits

2.5

Limited power sources

Inherently limited output

N/A

TRF No.:IECEN60950_1B

See 2.2.2 and 2.2.3. No direct
connection between SELV and
any primary circuit.

N/A

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Page 11 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

Impedance limited output

N/A

Overcurrent protective device limited output

N/A

Regulating network limited output under normal
operating and single fault condition

Regulating network limited output under normal
operating conditions and overcurrent protective
device limited output under single fault condition

N/A

Output voltage (V), output current (A), apparent
(See appended table)
power (VA)............................................................:



Current rating of overcurrent protective device (A)



2.6

Provisions for earthing and bonding

2.6.1

Protective earthing

Class II equipment.

2.6.2

Functional earthing

Secondary functional ground
separated to primary by
reinforced or double insulation.

2.6.3

Protective earthing and protective bonding
conductors

N/A

2.6.3.1

General

N/A

2.6.3.2

Size of protective earthing conductors

N/A

Rated current (A), cross-sectional area (mm2),
AWG .....................................................................:
2.6.3.3

Size of protective bonding conductors

N/A
P


N/A

Rated current (A), cross-sectional area (mm2),
AWG .....................................................................:



2.6.3.4

Resistance (Ω) of earthing conductors and their
terminations, test current (A) ................................:

N/A

2.6.3.5

Colour of insulation ...............................................:

N/A

2.6.4

Terminals

N/A

2.6.4.1

General

N/A

2.6.4.2

Protective earthing and bonding terminals

N/A

Rated current (A), type and nominal thread
diameter (mm) ......................................................:



2.6.4.3

Separation of the protective earthing conductor
from protective bonding conductors

N/A

2.6.5

Integrity of protective earthing

N/A

2.6.5.1

Interconnection of equipment

N/A

2.6.5.2

Components in protective earthing conductors
and protective bonding conductors

N/A

2.6.5.3

Disconnection of protective earth

N/A

2.6.5.4

Parts that can be removed by an operator

N/A

2.6.5.5

Parts removed during servicing

N/A

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Page 12 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

2.6.5.6

Corrosion resistance

N/A

2.6.5.7

Screws for protective bonding

N/A

2.6.5.8

Reliance on telecommunication network or cable
distribution system

2.7

Overcurrent and earth fault protection in primary circuits

2.7.1

Basic requirements

Equipment relies on 16A rated
fuse or circuit breaker of the wall
outlet installation protection of
the building installation in regard
to L to N short circuit.
Overcurrent protection is
provided by the fusing resistor.

Instructions when protection relies on building
installation

Not applicable for pluggable
equipment type A.

N/A

2.7.2

Faults not covered in 5.3

The protection device is well
dimensioned and mounted.

2.7.3

Short-circuit backup protection

Pluggable equipment type A.
Building installation is
considered as providing shortcircuit backup protection.

2.7.4

Number and location of protective devices ..........: Over current protection by one
built-in fusing resistor.

2.7.5

Protection by several devices

2.7.6

Warning to service personnel ...............................: No service work is necessary.

N/A

2.8

Safety interlocks

N/A

2.8.1

General principles

2.8.2

Protection requirements

N/A

2.8.3

Inadvertent reactivation

N/A

2.8.4

Fail-safe operation

N/A

2.8.5

Moving parts

N/A

2.8.6

Overriding

N/A

2.8.7

Switches and relays

N/A

2.8.7.1

Contact gaps (mm) ..............................................:

N/A

2.8.7.2

Overload test

N/A

2.8.7.3

Endurance test

N/A

2.8.7.4

Electric strength test

N/A

2.8.8

Mechanical actuators

N/A

2.9

Electrical insulation

TRF No.:IECEN60950_1B

Result – Remark

No TNV

Verdict

N/A

Only one fusing resistor
provided.

No safety interlock.

N/A

P
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Page 13 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

2.9.1

Properties of insulating materials

Natural rubber, asbestos or
hygroscopic material is not
used.

2.9.2

Humidity conditioning

120hr

Humidity (%) ........................................................: 95% R.H.



Temperature (°C) .................................................: 40°C



2.9.3

Grade of insulation

2.10

Clearances, creepage distances and distances through insulation

2.10.1

General

See 2.10.3, 2.10.4 and 2.10.5.

2.10.2

Determination of working voltage

The rms and the peak voltage
were measured on the direct
plug-in adaptor.
The unit was connected to a
240Vac power supply and
floating secondary circuits was
assumed to be earthed at
the point by which the highest
working voltage is obtained.
Results see appended table
2.10.2.

2.10.3

Clearances

See below and advantage of
annex G is not considered.

2.10.3.1

General

See below, Annex G was not
considered.

2.10.3.2

Clearances in primary circuits

Annex F and minimum
clearances considered.

2.10.3.3

Clearances in secondary circuits

2.10.3.4

Measurement of transient voltage levels

No transient voltage across the
clearance lower than due or
normal.

2.10.4

Creepage distances

(see appended table 2.10.3
and 2.10.4)

Insulation complies with subclauses 2.10, 4.5.1 and 5.2.

P
N/A

CTI tests ...............................................................: CTI rating for all materials of
min. 100.



2.10.5

Solid insulation

See below.

2.10.5.1

Minimum distance through insulation

(see appended table 2.10.5)

2.10.5.2

Thin sheet material

Thin sheet material was not
used as reinforced insulation.

N/A

2.10.5.3

Number of layers (pcs) .........................................:



Electric strength test



Printed boards
Distance through insulation

TRF No.:IECEN60950_1B

No multi-layer PCBs provided.

N/A
N/A

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Page 14 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Electric strength test for thin sheet insulating
material



Number of layers (pcs) .........................................:
2.10.5.4

Wound components

Verdict

N/A
Approved source of triple
insulated wire used as
seondary winding of T1.

Number of layers (pcs) .........................................: 3

Two wires in contact inside wound component;
By insulation tape.
angle between 45° and 90° ..................................:

2.10.6

Coated printed boards

2.10.6.1

General

N/A

2.10.6.2

Sample preparation and preliminary inspection

N/A

2.10.6.3

Thermal cycling

N/A

2.10.6.4

Thermal ageing (°C) .............................................:

N/A

2.10.6.5

Electric strength test

2.10.6.6

Abrasion resistance test

No coated printed boards.


N/A

Electric strength test
2.10.7

2.10.8

N/A



Enclosed and sealed parts ...................................: No hermetically sealed
component.

N/A

Temperature T1=T2 + Tma – Tamb +10K (°C)....:

N/A

Spacings filled by insulating compound................: No such component.

N/A

Electric strength test



2.10.9

Component external terminations

See appended table 2.10.2 and
2.10.3.

2.10.10

Insulation with varying dimensions

No such transformer used.

WIRING, CONNECTIONS AND SUPPLY

3.1

General

3.1.1

Current rating and overcurrent protection

Internal wiring is PVC insulated,
the wiring gauge is suitable for
current intended to be carried.

P
N/A

Internal wiring for primary power
distribution protected by built-in
fuse.
3.1.2

Protection against mechanical damage

Wires do not touch sharp
edges which could damage the
insulation and cause hazard.

3.1.3

Securing of internal wiring

The internal wiring are secured
by solder pins or tubing so that
loosening of the terminal
connections is unlikely.

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Page 15 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

3.1.4

Insulation of conductors

The insulation of the individual
conductors are suitable for the
application and the working
voltage. For the insulation
material see 3.1.1.
(see appended table 5.2)

3.1.5

Beads and ceramic insulators

Not used.

N/A

3.1.6

Screws for electrical contact pressure

No such screws provided.

N/A

3.1.7

Insulating materials in electrical connections

All current carrying connections
are metal to metal.

N/A

3.1.8

Self-tapping and spaced thread screws

Not used.

N/A

3.1.9

Termination of conductors

All conductors are reliable
secured.

10 N pull test

Force of 10 N applied to the
termination points of the
conductors.

3.1.10

Sleeving on wiring

No sleeving used to provide
supplementary insulation.

N/A

3.2

Connection to an a.c. mains supply or a d.c. mains supply

3.2.1

Means of connection ............................................: A mains plug, that is part of
direct plug-in equipment

3.2.1.1

Connection to an a.c. mains supply

See above

3.2.1.2

Connection to a d.c. mains supply

AC Source

N/A

3.2.2

Multiple supply connections

Only one supply connection.

N/A

3.2.3

Permanently connected equipment

Not permanently connected
equipment.

N/A

Number of conductors, diameter (mm) of cable
and conduits ........................................................:

Verdict
P



3.2.4

Appliance inlets

Direct plug-in equipment.

N/A

3.2.5

Power supply cords

No power cord.

N/A

3.2.5.1

AC power supply cords

N/A

Type......................................................................:



Rated current (A), cross-sectional area (mm2),
AWG .....................................................................:



3.2.5.2

DC power supply cords

AC Source.

N/A

3.2.6

Cord anchorages and strain relief

No power cord.

N/A

Mass of equipment (kg), pull (N) ........................:



Longitudinal displacement (mm) ..........................:



3.2.7

Protection against mechanical damage

Direct plug-in equipment. No
sharp edges.

N/A

3.2.8

Cord guards

No cord guard provided.

N/A

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Page 16 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

D (mm); test mass (g) ..........................................:



Radius of curvature of cord (mm).........................:



3.2.9

Supply wiring space

3.3

Wiring terminals for connection of external conductors

N/A

3.3.1

Wiring terminals

N/A

3.3.2

Connection of non-detachable power supply
cords

N/A

3.3.3

Screw terminals

N/A

3.3.4

Conductor sizes to be connected

N/A

Not permanent connection or
non-detachable power cord
type.

Direct plug-in equipment.

Rated current (A), cord/cable type, cross-sectional
area (mm2) ...........................................................:
3.3.5

N/A



Wiring terminal sizes

N/A

Rated current (A), type and nominal thread
diameter (mm) .....................................................:



3.3.6

Wiring terminals design

N/A

3.3.7

Grouping of wiring terminals

N/A

3.3.8

Stranded wire

N/A

3.4

Disconnection from the mains supply

3.4.1

General requirement

Disconnect device provided.

3.4.2

Disconnect devices

Plug of this direct plug-in
equipment was used as
disconnected device.

3.4.3

Permanently connected equipment

Not permanently connected
equipment.

3.4.4

Parts which remain energized

There is no parts remained with
hazardous voltage or energy in
the equipment when SPS is
separated from AC mains.

3.4.5

Switches in flexible cords

No flexible cords.

3.4.6

Single-phase equipment and d.c. equipment

The mains plug disconnects
both poles simultaneously.

3.4.7

Three-phase equipment

Single phase equipment.

N/A

3.4.8

Switches as disconnect devices

See sub-clause 3.4.2.

N/A

3.4.9

Plugs as disconnect devices

See sub-clause 3.4.2.

N/A

3.4.10

Interconnected equipment

No interconnections using
hazardous voltages.

N/A

3.4.11

Multiple power sources

Only one supply connection
provided.

N/A

TRF No.:IECEN60950_1B

N/A
P

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Page 17 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

3.5

Interconnection of equipment

3.5.1

General requirements

3.5.2

Types of interconnection circuits ..........................: Interconnection circuits of
SELV through the connector.
No ELV interconnection
circuits.

3.5.3

ELV circuits as interconnection circuits

PHYSICAL REQUIREMENTS

4.1

Stability
Angle of 10°

Result – Remark

Verdict
P

This power supply is not
considered for connection to
TNV.

No ELV interconnection

N/A
P
N/A

Direct plug-in equipment.

Test: force (N).......................................................:

N/A
N/A

4.2

Mechanical strength

4.2.1

General

See below. After tests, unit
comply with 2.1.1, 2.6.1, 2.10
and 4.4.1.

4.2.2

Steady force test, 10 N

10N applied to components
other than parts serving as an
enclosure.

4.2.3

Steady force test, 30 N

No internal enclosure.

4.2.4

Steady force test, 250 N

250N applied to outer enclosure.
No energy or other hazards.

4.2.5

Impact test

Direct plug-in equipment.

N/A
P
N/A

Fall test

N/A

Swing test

N/A

4.2.6

Drop test

No hazard as result from drop
test.

4.2.7

Stress relief test

After 7 hours at temperature of
75°C and cooling down to room
temperature, no shrinkage and
distortion or loosening any
enclosure part was noticeable
on the adapter.

Test was performed for all
sources of enclosure material.
4.2.8

Cathode ray tubes

No CRT provided.

Picture tube separately certified ...........................:

N/A

4.2.9

High pressure lamps

4.2.10

Wall or ceiling mounted equipment; force (N) .....: Direct plug-in equipment.

TRF No.:IECEN60950_1B

N/A

No High pressure lamps
provided.

N/A
N/A

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Page 18 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

4.3

Design and construction

4.3.1

Edges and corners

4.3.2

Handles and manual controls; force (N) ...............: No handles or controls provided.

N/A

4.3.3

Adjustable controls

No controls provided.

N/A

4.3.4

Securing of parts

No connection likely to be
exposed to mechanical stress is
provided in unit.

4.3.5

Connection of plugs and sockets

No mismating of connectors,
plugs or sockets possible.

4.3.6

Direct plug-in equipment

The prevention of imposing to
undue strain on the socketoutlet was done by construction
of the plug of adaptor.

P
All edges and corners are
rounded and /or smoothed.

For European plug: 0.02Nm;
For British plug: 0.02Nm;
For Australian plug: 0.02Nm;
For Indian plug: 0.05Nm
Dimensions (mm) of mains plug for direct plug-in : (See attached partial test
reports)

Torque and pull test of mains plug for direct
See above.
plug-in; torque (Nm); pull (N) ................................:

4.3.7

Heating elements in earthed equipment

No heating elements provided.

N/A

4.3.8

Batteries

No batteries provided.

N/A

4.3.9

Oil and grease

No heating elements provided.

N/A

4.3.10

Dust, powders, liquids and gases

Equipment in intended use not
considered to be exposed to
these.

N/A

4.3.11

Containers for liquids or gases

No container for liquid or gas.

N/A

4.3.12

Flammable liquids.................................................: No such flammable liquid.

N/A

Quantity of liquid (l) ...............................................:

N/A

Flash point (°C).....................................................:

N/A

4.3.13

Radiation; type of radiation ..................................: No optical radiation present.

N/A

4.3.13.1

General

N/A

4.3.13.2

Ionizing radiation

N/A

4.3.13.3

Measured radiation (pA/kg) .................................:



Measured high-voltage (kV) ................................:



Measured focus voltage (kV) ...............................:



CRT markings .....................................................:



Effect of ultraviolet (UV) radiation on materials

N/A

Part, property, retention after test, flammability
classification ........................................................:

N/A

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Page 19 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

4.3.13.4

Human exposure to ultraviolet (UV) radiation ......:

4.3.13.5

Laser (including LEDs)

Result – Remark

Verdict
N/A

No optical radiation present.

N/A

Laser class ...........................................................:



4.3.13.6

Other types ..........................................................:

N/A

4.4

Protection against hazardous moving parts

N/A

4.4.1

General

4.4.2

Protection in operator access areas

N/A

4.4.3

Protection in restricted access locations

N/A

4.4.4

Protection in service access areas

N/A

4.5

Thermal requirements

4.5.1

Maximum temperatures

No moving parts.

N/A

P
See appended table 4.5.1.

Normal load condition per Annex L.......................: See 1.6.2.

4.5.2

Resistance to abnormal heat

4.6

Openings in enclosures

4.6.1

Top and side openings

See appended table 4.5.2.

P
No openings

Dimensions (mm) ................................................:
4.6.2

Bottoms of fire enclosures


No openings

Construction of the bottom ...................................:



4.6.3

Doors or covers in fire enclosures

No such things.

N/A

4.6.4

Openings in transportable equipment

No opening.

N/A

4.6.5

Adhesives for constructional purposes

No adhesive.

N/A

Conditioning temperature (°C)/time (weeks) ........:



4.7

Resistance to fire

4.7.1

Reducing the risk of ignition and spread of flame

Use of materials with the
required flammability classes.

Method 1, selection and application of
components wiring and materials

(see appended table 4.7)

Method 2, application of all of simulated fault
condition tests
4.7.2

Conditions for a fire enclosure

TRF No.:IECEN60950_1B

N/A
See below.

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Page 20 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

4.7.2.1

Parts requiring a fire enclosure

With having the following parts:

Verdict
P

Components in primary
Components in secondary
Components having
unenclosed arcing parts at
hazardous voltage or energy
level
Insulated wiring
The fire enclosure is required.
4.7.2.2

Parts not requiring a fire enclosure

4.7.3

Materials

4.7.3.1

General

Parts mounted on PCB of
flammability class V-0 or better.

4.7.3.2

Materials for fire enclosures

The fire enclosure is V-1 or
better material.

4.7.3.3

Materials for components and other parts outside
fire enclosures

No part outside fire enclosure.

4.7.3.4

Materials for components and other parts inside
fire enclosures

Internal components except
small parts are V-2 or better.

4.7.3.5

Materials for air filter assemblies

No air filters provided.

N/A

4.7.3.6

Materials used in high-voltage components

No high voltage components
provided.

N/A

ELECTRICAL REQUIREMENTS AND SIMULATED ABNORMAL CONDITIONS

5.1

Touch current and protective conductor current

5.1.1

General

See sub-clauses 5.1.2 to 5.1.6.

5.1.2

Equipment under test (EUT)

EUT has only one mains
connection.

5.1.3

Test circuit

Equipment of figure 5A used.

5.1.4

Application of measuring instrument

Using measuring instrument in
annex D.

5.1.5

Test procedure

The touch current was
measured from mains to DC
output connector and to a 100
mm × 200 mm metal foil
wrapped on accessible nonconductive parts (plastic
enclosure).

5.1.6

Test measurements

See below.

N/A
P

Test voltage (V) ...................................................: See appended table 5.1.6.



Measured touch current (mA) ..............................: See appended table 5.1.6.



Max. allowed touch current (mA) .........................: See appended table 5.1.6.



Measured protective conductor current (mA) ......:



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Page 21 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Max. allowed protective conductor current (mA) .:

Verdict


5.1.7

Equipment with touch current exceeding 3.5 mA : Neither stationary permanently
connected equipment nor
stationary pluggable equipment
type B.

N/A

5.1.8

Touch currents to and from telecommunication
No TNV.
networks and cable distribution systems and from
telecommunication networks

N/A

5.1.8.1

Limitation of the touch current to a
telecommunication network and a cable
distribution system

N/A

Test voltage (V) ...................................................:



Measured touch current (mA) ..............................:



Max. allowed touch current (mA) .........................:



5.1.8.2

Summation of touch currents from
telecommunication networks ................................:

N/A

5.2

Electric strength

5.2.1

General

(see appended table 5.2)

5.2.2

Test procedure

(see appended table 5.2)

5.3

Abnormal operating and fault conditions

5.3.1

Protection against overload and abnormal
operation

P
Output overload test, the most
unfavorable load test.

(see appended table 5.3)
5.3.2

Motors

No motors.

5.3.3

Transformers

With the shorted o/p of the
transformer, no high
temperature of the transformer
was recorded.

N/A
P

Results of the short-circuit tests
see appended table 5.3 and
Annex C.
5.3.4

Functional insulation .............................................: Method c). Test results see
appended table 5.3.

5.3.5

Electromechanical components

No electromechanical
component provided.

5.3.6

Simulation of faults

Results see appended table.

5.3.7

Unattended equipment

None of the listed components
was provided.

N/A

5.3.8

Compliance criteria for abnormal operating and
fault conditions

No fire propagated beyond the
equipment. No molten metal
was emitted. Electric strength
test primary to SELV was
passed.

TRF No.:IECEN60950_1B

P
N/A
P

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Page 22 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

CONNECTION TO TELECOMMUNICATION NETWORKS

N/A

6.1

Protection of telecommunication network service persons, and users of other
equipment connected to the network, from hazards in the equipment

N/A

6.1.1

Protection from hazardous voltages

N/A

6.1.2

Separation of the telecommunication network from earth

N/A

6.1.2.1

Requirements

N/A

No TNV.

Verdict

Test voltage (V) ...................................................:



Current in the test circuit (mA) ............................:



6.1.2.2

Exclusions.............................................................:

N/A

6.2

Protection of equipment users from overvoltages on telecommunication networks

N/A

6.2.1

Separation requirements

N/A

6.2.2

Electric strength test procedure

N/A

6.2.2.1

Impulse test

N/A

6.2.2.2

Steady-state test

N/A

6.2.2.3

Compliance criteria

N/A

6.3

Protection of the telecommunication wiring system from overheating

N/A

No TNV.

Max. output current (A) .........................................: No TNV.



Current limiting method ........................................:



CONNECTION TO CABLE DISTRIBUTION SYSTEMS

N/A

7.1

Protection of cable distribution system service
persons, and users of other equipment
connected to the system, from hazardous
voltages in the equipment

N/A

7.2

Protection of equipment users from overvoltages
on the cable distribution system

N/A

7.3

Insulation between primary circuits and cable
distribution systems

N/A

7.3.1

General

N/A

7.3.2

Voltage surge test

N/A

7.3.3

Impulse test

N/A

ANNEX A, TESTS FOR RESISTANCE TO HEAT AND FIRE

N/A

A.1

Flammability test for fire enclosures of movable equipment having a total mass
exceeding 18 kg, and of stationary equipment (see 4.7.3.2)

N/A

A.1.1

Samples................................................................:



Wall thickness (mm) .............................................:



TRF No.:IECEN60950_1B

Not connected to cable
distribution system

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Page 23 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

A.1.2

Conditioning of samples; temperature (°C) ..........:

N/A

A.1.3

Mounting of samples ............................................:

N/A

A.1.4

Test flame (see IEC 60695-11-3)

N/A

Flame A, B, C or D ...............................................:

Verdict



A.1.5

Test procedure

N/A

A.1.6

Compliance criteria

N/A

Sample 1 burning time (s) ....................................:



Sample 2 burning time (s) ....................................:



Sample 3 burning time (s) ....................................:



A.2

Flammability test for fire enclosures of movable equipment having a total mass not
exceeding 18 kg, and for material and components located inside fire enclosures
(see 4.7.3.2 and 4.7.3.4)

A.2.1

Samples, material.................................................:



Wall thickness (mm) .............................................:



N/A

A.2.2

Conditioning of samples

N/A

A.2.3

Mounting of samples ...........................................:

N/A

A.2.4

Test flame (see IEC 60695-11-4)

N/A

Flame A, B or C ...................................................:



A.2.5

Test procedure

N/A

A.2.6

Compliance criteria

N/A

A.2.7

Sample 1 burning time (s) ....................................:



Sample 2 burning time (s) ....................................:



Sample 3 burning time (s) ....................................:



Alternative test acc. To IEC 60695-2-2, cl. 4 and
8

N/A

Sample 1 burning time (s) ....................................:



Sample 2 burning time (s) ....................................:



Sample 3 burning time (s) ....................................:



A.3

Hot flaming oil test (see 4.6.2)

N/A

A.3.1

Mounting of samples

N/A

A.3.2

Test procedure

N/A

A.3.3

Compliance criterion

N/A

ANNEX B, MOTOR TESTS UNDER ABNORMAL CONDITIONS (see 4.7.2.2 and
5.3.2)

N/A

B.1

General requirements

N/A

No motor provided.

Position ................................................................:



Manufacturer ........................................................:



Type .....................................................................:



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Page 24 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Rated values .......................................................:

Verdict


B.2

Test conditions

N/A

B.3

Maximum temperatures

N/A

B.4

Running overload test

N/A

B.5

Locked-rotor overload test

N/A

Test duration (days) .............................................:



Electric strength test: test voltage (V) ..................:



B.6

Running overload test for d.c. motors in
secondary circuits

N/A

B.7

Locked-rotor overload test for d.c. motors in secondary circuits

N/A

B.7.1

Test procedure

N/A

B.7.2

Alternative test procedure; test time (h)................:

N/A

B.7.3

Electric strength test

N/A

B.8

Test for motors with capacitors

N/A

B.9

Test for three-phase motors

N/A

B.10

Test for series motors

N/A

Operating voltage (V) ...........................................:



ANNEX C, TRANSFORMERS (see 1.5.4 and 5.3.3)

Position ................................................................: T1



Manufacturer ........................................................: See appended table 1.5.1



Type .....................................................................: See appended table 1.5.1



Rated values .......................................................: Class B



Method of protection .............................................: By protection circuit design.



C.1

Overload test

See appended table 5.3.

C.2

Insulation

See appended table C.2.

Protection from displacement of windings ............: By insulation tape

ANNEX D, MEASURING INSTRUMENTS FOR TOUCH-CURRENT TESTS
(see 5.1.4)

D.1

Measuring instrument

D.2

Alternative measuring instrument

N/A

ANNEX E, TEMPERATURE RISE OF A WINDING (see 1.4.13)

N/A

ANNEX F, MEASUREMENT OF CLEARANCES AND CREEPAGE DISTANCES
(see 2.10)

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Page 25 of 73
IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

ANNEX G, ALTERNATIVE METHOD FOR DETERMINING MINIMUM
CLEARANCES

N/A

G.1

Summary of the procedure for determining
minimum clearances

N/A

G.2

Determination of mains transient voltage (V) .......:

N/A

G.2.1

AC mains supply

N/A

G.2.2

DC mains supply

N/A

G.3

Determination of telecommunication network
transient voltage (V)..............................................:

N/A

G.4

Determination of required withstand voltage (V)...:

N/A

G.5

Measurement of transient levels (V).....................:

N/A

G.6

Determination of minimum clearances .................:

N/A

ANNEX H, IONIZING RADIATION (see 4.3.13)

N/A

ANNEX J, TABLE OF ELECTROCHEMICAL POTENTIALS (see 2.6.5.6)

N/A

Metal used ...........................................................: No risk of corrosion.



ANNEX K, THERMAL CONTROLS (see 1.5.3 and 5.3.7)

N/A

K.1

Making and breaking capacity

N/A

K.2

Thermostat reliability; operating voltage (V) .........:

N/A

K.3

Thermostat endurance test; operating voltage
(V) .......................................................................:

N/A

K.4

Temperature limiter endurance; operating voltage
(V) ........................................................................:

N/A

K.5

Thermal cut-out reliability

N/A

K.6

Stability of operation

N/A

ANNEX L, NORMAL LOAD CONDITIONS FOR SOME TYPES OF ELECTRICAL
BUSINESS EQUIPMENT (see 1.2.2.1 and 4.5.1)

L.1

Typewriters

N/A

L.2

Adding machines and cash registers

N/A

L.3

Erasers

N/A

L.4

Pencil sharpeners

N/A

L.5

Duplicators and copy machines

N/A

L.6

Motor-operated files

N/A

L.7

Other business equipment

ANNEX M, CRITERIA FOR TELEPHONE RINGING SIGNALS (see 2.3.1)

N/A

M.1

Introduction

N/A

TRF No.:IECEN60950_1B

No telephone signal.

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Verdict

M.2

Method A

N/A

M.3

Method B

N/A

M.3.1

Ringing signal

N/A

M.3.1.1

Frequency (Hz) ....................................................:



M.3.1.2

Voltage (V) ...........................................................:



M.3.1.3

Cadence; time (s), voltage (V) .............................:



M.3.1.4

Single fault current (mA) .......................................:



M.3.2

Tripping device and monitoring voltage ................:

N/A

M.3.2.1

Conditions for use of a tripping device or a
monitoring voltage

N/A

M.3.2.2

Tripping device

N/A

M.3.2.3

Monitoring voltage (V)...........................................:

N/A

ANNEX N, IMPULSE TEST GENERATORS (see 2.10.3.4, 6.2.2.1, 7.3.2 and
clause G.5)

N/A

N.1

ITU-T impulse test generators

N/A

N.2

IEC 60065 impulse test generator

N/A

ANNEX P, NORMATIVE REFERENCES

ANNEX Q, BIBLIOGRAPHY

ANNEX R, EXAMPLES OF REQUIREMENTS FOR QUALITY CONTROL
PROGRAMMES

N/A

R.1

Minimum separation distances for unpopulated
coated printed boards (see 2.10.6)

N/A

R.2

Reduced clearances (see 2.10.3)

N/A

ANNEX S, PROCEDURE FOR IMPULSE TESTING (see 6.2.2.3)

N/A

S.1

Test equipment

N/A

S.2

Test procedure

N/A

S.3

Examples of waveforms during impulse testing

N/A

ANNEX T, GUIDANCE ON PROTECTION AGAINST INGRESS OF WATER
(see 1.1.2)

N/A


ANNEX U, INSULATED WINDING WIRES FOR USE WITHOUT INTERLEAVED
INSULATION (see 2.10.5.4)

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Clause

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Result – Remark
Approved TIW used.

Verdict


ANNEX V, AC POWER DISTRIBUTION SYSTEMS (see 1.6.1)

V.1

Introduction

V.2

TN power distribution systems

V.3

TT power systems

V.4

IT power systems

ANNEX W, SUMMATION OF TOUCH CURRENTS

W.1

Touch current from electronic circuits

W.1.2

Earthed circuits

N/A

W.2

Interconnection of several equipments

N/A

W.2.1

Isolation

N/A

W.2.2

Common return, isolated from earth

N/A

W.2.3

Common return, connected to protective earth

N/A

ANNEX X, MAXIMUM HEATING EFFECT IN TRANSFORMER TESTS
(see clause C.1)

X.1

Determination of maximum input current

X.2

Overload test procedure

ANNEX Y, ULTRAVIOLET LIGHT CONDITIONING TEST (see 4.3.13.3)

N/A

Y.1

Test apparatus .....................................................:

N/A

Y.2

Mounting of test samples .....................................:

N/A

Y.3

Carbon-arc light-exposure apparatus ..................:

N/A

Y.4

Xenon-arc light exposure apparatus ....................:

N/A

TRF No.:IECEN60950_1B

N/A
IT-power system for Norway.

See table 5.1.6

P
N/A
P

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IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

EU Group Differences [C],
EU Special National Conditions [S], EU A-Deviations [A]
(EN 60950-1:2001, Annex ZB and Annex ZC)
General

C: Delete all the "country" notes in the reference
document according to the following list:
1.1.5
Note 2
1.7.2
Note 4
2.2.3
Note
2.3.3
Note 1, 2
2.10.3.1 Note 4
3.2.5.1 Note 2
4.7.3.1 Note 2
6.2.2
Note
7
Note 4
G2.1
Note 1, 2

1.5.8
1.7.12
2.2.4
2.3.4
3.2.1.1
4.3.6
6.1.2.1
6.2.2.1
7.1
Annex H

Note 2
Note 2
Note
Note 2,3
Note
Note 1,2
Note
Note 2
Note
Note 2

1.6.1
2.6
2.3.2
2.7.1
3.2.3
4.7.2.2
6.1.2.2
6.2.2.2

Verdict
P

Deleted.

N/A

Note
Note
Note 2, 7, 8
Note
Note 1, 2
Note
Note
Note

1.2.4.1

S (DK): Certain types of Class I appliances (see
3.2.1.1) may be provided with a plug not
establishing earthing conditions when inserted
into Danish socket-outlets.

Class II equipment.

N/A

1.5.1

A (SE, Ordinance 1990:944 and
CH, Ordinance on environmentally hazardous
substances SR 814.013, Annex 3.2, Mercury):
Add NOTE – Switches containing mercury such as

No switch.

N/A

1.5.8

S (NO): Due to the IT power system used (see
annex V, Fig. V.7), capacitors are required to be
rated for the applicable line-to-line voltage
(230 V).

Class II equipment.

N/A

1.7.2

S (FI, NO, SE): CLASS I PLUGGABLE EQUIPMENT
intended for connection to other
equipment or a network shall, if safety relies on
connection to protective earth or if surge
suppressors are connected between the network
terminals and accessible parts, have a marking
stating that the equipment must be connected to
an earthed mains socket-outlet.

Class II equipment.

N/A

FI: "Laite on liitettävä suojamaadoituskoskettimilla Class II equipment.
varustettuun pistorasiaan"

N/A

NO: "Apparatet må tilkoples jordet stikkontakt"

Class II equipment.

N/A

SE: "Apparaten skall anslutas till jordat uttag"

Class II equipment.

N/A

A (DK, Heavy Current Regulations): Supply cords Class II equipment.
of class I equipment, which is delivered without a
plug, must be provided with a visible tag with the
following text:

N/A

thermostats, relays and level controllers are not allowed.

TYPE A

The marking text in the applicable countries shall
be as follows:

Vigtigt!
Lederen med grøn/gul isolation må kun tilsluttes
en klemme mærket
eller
If essential for the safety of the equipment, the
tag must in addition be provided with a diagram
which shows the connection of the other
conductors, or be provided with the following text:
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IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

"For tilslutning af de øvrige ledere, se
medfølgende instalationsvejledning."
1.7.5

S (DK): Socket-outlets for providing power to
other equipment shall be in accordance with the
Heavy Current Regulations, Section 107-2-D1,
Standard Sheet DK 1-3a, DK 1-5a or DK 1-7a,
when used on Class I equipment. For stationary
equipment the socket-outlet shall be in accordance with Standard Sheet DK 1-1b or DK 1-5a.

No socket-outlet.

N/A

1.7.5

A (DK, Heavy Current Regulations):
No socket outlet.
CLASS II EQUIPMENT shall not be fitted with socketoutlets for providing power to other equipment.

N/A

1.7.12

A (DE, Gesetz über technische Arbeitsmittel
Not labour equipment.
(Gerätesicherheitsgesetz) [Law on technical
rd
labour equipment {Equipment safety law}], of 23
rd
nd
October 1992, Article 3, 3 paragraph, 2
sentence, together with the "Allgemeine
Verwaltungsvorschrift zur Durchführung des
Zweiten Abschnitts des Gerätesicherheitsgesetzes" [General administrative regulation on
the execution of the Second Section of the
th
Equipment safety law], of 10 January 1996,
th
article 2, 4 paragraph item 2):
Directions for use with rules to prevent certain
hazards for (among others) maintenance of the
technical labour equipment, also for imported
technical labour equipment shall be written in the
German language.

N/A

NOTE: Of this requirement, rules for use even only by service
personnel are not exempted.

1.7.15

No batteries.

N/A

A (DE, Regulation on protection against hazards No radiation.
th
by X-ray, of 8 January 1987, Article 5 [Operation
of X-ray emission source], clauses 1 to 4):
a) A licence is required by those who operate an
X-ray emission source.
b) A licence in accordance with Cl. 1 is not
required by those who operate an X-ray emission
source on which the electron acceleration voltage
does not exceed 20 kV if
1) the local dose rate at a distance of 0,1 m from
the surface does not exceed 1 Sv/h and
2) it is adequately indicated on the X-ray emission
source that
i) X-rays are generated and
ii) the electron acceleration voltage must not
exceed the maximum value stipulated by
the manufacturer or importer.
c) A licence in accordance with Cl. 1 is also not
required by persons who operate an X-ray
emission source on which the electron
acceleration voltage exceeds 20 kV if

N/A

A (CH, Ordinance on environmentally hazardous
substances SR 814.013):
Annex 4.10 of SR 814.013 applies for batteries.

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IEC 60950-1 / EN 60950-1

Clause

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Result – Remark

Verdict

1) the X-ray emission source has been granted a
type approval and
2) it is adequately indicated on the X-ray emission
source that
i) X-rays are generated
ii) the device stipulated by the manufacturer or
importer guarantees that the maximum
permissible local dose rate in accordance
with the type approval is not exceeded and
iii) the electron acceleration voltage must not
exceed the maximum value stipulated by the
manufacturer or importer.
d) Furthermore, a licence in accordance with
Cl. 1 is also not required by persons who operate
X-ray emission sources on which the electron
acceleration voltage does not exceed 30 kV if
1) the X-rays are generated only by intrinsically
safe CRTs complying with Enclosure III, No. 6,
2) the values stipulated in accordance with
Enclosure III, No. 6.2 are limited by technical
measures and specified in the device and
3) it is adequately indicated on the X-ray emission
source that the X-rays generated are adequately screened by the intrinsically safe CRT.
2.2.4

S (NO): Requirements according to this annex,
1.7.2 and 6.1.2.1 apply.

Not TNV.

N/A

2.3.2

S (NO): Requirements according to this annex,
6.1.2.1 apply.

Not TNV.

N/A

2.3.3 and
2.3.4

S (NO): Requirements according to this annex,
1.7.2 and 6.1.2.1 apply.

Not TNV.

N/A

2.6.3.3

S (GB): The current rating of the circuit shall be
taken as 13 A, not 16 A.

Class II equipment.

N/A

2.7.1

C: Replace the subclause as follows:

Replaced.

Basic requirements
To protect against excessive current, shortcircuits and earth faults in PRIMARY CIRCUITS,
protective devices shall be included either as
integral parts of the equipment or as parts of the
building installation, subject to the following, a), b)
and c):
a) except as detailed in b) and c), protective
devices necessary to comply with the
requirements of 5.3 shall be included as parts of
the equipment;
b) for components in series with the mains input
to the equipment such as the supply cord,
appliance coupler, r.f.i. filter and switch, shortcircuit and earth fault protection may be provided
by protective devices in the building installation;
c) it is permitted for PLUGGABLE EQUIPMENT TYPE B
or PERMANENTLY CONNECTED EQUIPMENT, to rely
on dedicated overcurrent and short-circuit
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IEC 60950-1 / EN 60950-1

Clause

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Result – Remark

Verdict

protection in the building installation, provided
that the means of protection, e.g. fuses or circuit
breakers, is fully specified in the installation
instructions.
If reliance is placed on protection in the building
installation, the installation instructions shall so
state, except that for PLUGGABLE EQUIPMENT TYPE
A the building installation shall be regarded as
providing protection in accordance with the rating
of the wall socket outlet.
S (GB): To protect against excessive currents
Built-in fusible resistor was
and short-circuits in the PRIMARY CIRCUIT OF
used as protective device.
DIRECT PLUG-IN EQUIPMENT, protective device shall
be included as integral parts of the DIRECT PLUGIN EQUIPMENT.

N/A

2.7.2

C: Void.

2.10.2

C: Replace in the first line "(see also 1.4.7)" by
"(see also 1.4.8)".

Replaced.

2.10.3.1

S (NO): Due to the IT power distribution system
used (see annex V, Fig. V.7), the A.C. MAINS
SUPPLY voltage is considered to be equal to the
line-to-line voltage and will remain at 230 V in
case of a single earth fault

Considered.

3.2.1.1

S (CH): Supply cords of equipment having a
RATED CURRENT not exceeding 10 A shall be
provided with a plug complying with SEV 1011 or
IEC 60884-1 and one of the following dimension
sheets:

Direct plug-in equipment.

N/A

SEV 6532-2.1991, Plug type 15, 3P+N+PE 250/400 V, 10 A
SEV 6533-2.1991, Plug type 11, L+N
250 V, 10 A
SEV 6534-2.1991, Plug type 12, L+N+PE 250 V, 10 A

In general, EN 60309 applies for plugs for
currents exceeding 10 A. However, a 16 A plug
and socket-outlet system is being introduced in
Switzerland, the plugs of which are according to
the following dimension sheets, published in
February 1998:
SEV 5932-2.1998, Plug type 25, 3L+N+PE 230/400 V, 16 A
SEV 5933-2.1998, Plug type 21, L+N
250 V, 16 A
SEV 5934-2.1998, Plug type 23, L+N+PE 250 V, 16 A

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IEC 60950-1 / EN 60950-1

Clause

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Result – Remark

Verdict

S (DK): Supply cords of single-phase equipment
having a rated current not exceeding 13 A shall
be provided with a plug according to the Heavy
Current Regulations, Section 107-2-D1.

Direct plug-in equipment.

N/A

Direct plug-in equipment.

N/A

Direct plug-in equipment.

N/A

Direct plug-in equipment.

N/A

CLASS I EQUIPMENT provided with socket-outlets
with earth contacts or which are intended to be
used in locations where protection against
indirect contact is required according to the wiring
rules shall be provided with a plug in accordance
with standard sheet DK 2-1a or DK 2-5a.

If ply-phase equipment and single-phase
equipment having a RATED CURRENT exceeding
13 A is provided with a supply cord with a plug,
this plug shall be in accordance with the Heavy
Current Regulations, Section 107-2-D1 or
EN 60309-2.
S (ES): Supply cords of single-phase equipment
having a rated current not exceeding 10 A shall
be provided with a plug according to
UNE 20315:1994.
Supply cords of single-phase equipment having a
rated current not exceeding 2,5 A shall be
provided with a plug according to
UNE-EN 50075:1993.
CLASS I EQUIPMENT provided with socket-outlets
with earth contacts or which are intended to be
used in locations where protection against
indirect contact is required according to the wiring
rules, shall be provided with a plug in accordance
with standard UNE 20315:1994.

If poly-phase equipment is provided with a supply
cord with a plug, this plug shall be in accordance
with UNE-EN 60309-2.
S (GB): Apparatus which is fitted with a flexible
cable or cord and is designed to be connected to
a mains socket conforming to BS 1363 by means
of that flexible cable or cord and plug, shall be
fitted with a '
standard plug'in accordance with
Statutory Instrument 1768:1994 – The Plugs and
Socket etc. (Safety) Regulations 1994, unless
exempted by those regulations.
NOTE – '
Standard plug'is defined in SI 1768:1994 and
essentially means an approved plug conforming to BS 1363
or an approved conversion plug.

S (IE): Apparatus which is fitted with a flexible
cable or cord and is designed to be connected to
a mains socket conforming to I.S. 411 by means
of that flexible cable or cord and plug, shall be
fitted with a 13 A plug in accordance with
Statutory Instrument 525:1997 – National
Standards Authority of Ireland (section 28) (13 A
Plugs and Conversion Adaptors for Domestic
Use) Regulations 1997.

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Clause

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Result – Remark

Verdict

3.2.3

C: Delete Note 1 and in Table 3A, delete the
conduit sizes in parentheses.

Deleted.

N/A

3.2.5.1

C: Replace

Replaced.

N/A

"60245 IEC 53" by "H05 RR-F";
"60227 IEC 52" by "H03 VV-F or H03 VVH2-F";
"60227 IEC 53" by "H05 VV-F or H05 VVH2-F2".
In Table 3B, replace the first four lines by the
following:
Up to and including 6
2)
Over 6 up to and including 10 (0,75)
3)
Over 10 up to and including 16 (1,0)

0,75
1,0
1,5

In the Conditions applicable to Table 3B delete
1)
the words "in some countries" in condition .
In Note 1, applicable to Table 3B, delete the
second sentence.
3.2.5.1

S (GB): A power supply cord with conductor of
2
1,25 mm is allowed for equipment with a rated
current over 10 A and up to and including 13 A.

Direct plug-in equipment.

N/A

3.3.4

C: In table 3D, delete the fourth line: conductor
sizes for 10 to 13 A, and replace with the
following:

Deleted.

N/A

"Over 10 up to and including 16

1,5 to 2,5

1,5 to 4"

Delete the fifth line: conductor sizes for 13 to
16 A.
3.3.4

S (GB): The range of conductor sizes of flexible
cords to be accepted by terminals for equipment
with a RATED CURRENT of over 10 A up to and
including 13 A is:
2
2
- 1,25 mm to 1,5 mm nominal cross-sectional
area.

Direct plug-in equipment.

4.3.6

S (GB): The torque test is performed using a
socket outlet complying with BS 1363 and the
plug part of DIRECT PLUG-IN EQUIPMENT shall be
assessed to BS 1363: Part 1, 12.1, 12.2, 12.3,
12.9, 12.11, 12.12, 12.16 and 12.17, except that
the test of 12.17 is performed at not less than
125 °C.

See IEC 60950-1 and attached
BS 1363 test report.

See IEC 60950-1 and attached
S (IE): DIRECT PLUG-IN EQUIPMENT is known as
BS 1363 test report.
plug similar devices. Such devices shall comply
with Statutory Instrument 526:1997 – National
Standards Authority of Ireland (Section 28)
(Electrical plugs, plug similar devices and sockets
for domestic use) Regulations, 1997.

4.3.13.6

C: Add the following note:

Added.

N/A

No TNV.

N/A

NOTE Attention is drawn to 1999/519/EC: Council
Recommendation on the limitation of exposure of the general
public to electromagnetic fields 0 Hz to 300 GHz. Standards
taking into account this recommendation are currently under
development.

6.1.2.1

S (FI, NO, SE): Add the following text between
the first and second paragraph:

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IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

If this insulation is solid, including insulation
forming part of a component, it shall at least
consist of either
- two layers of thin sheet material, each of which
shall pass the electric strength test below, or
- one layer having a distance through insulation of
at least 0,4 mm, which shall pass the electric
strength test below.
If this insulation forms part of a semiconductor
component (e.g. an optocoupler), there is no
distance through insulation requirement for the
insulation consisting of an insulating compound
completely filling the casing, so that CLEARANCES
AND CREEPAGE DISTANCES do not exist, if the
component passes the electric strength test in
accordance with the compliance clause below
and in addition
- passes the tests and inspection criteria of 2.10.8
with an electric strength test of 1,5 kV multiplied
by 1,6 (the electric strength test of 2.10.7 shall be
performed using 1,5 kV), and
- is subject to ROUTINGE TESTING for electric
strength during manufacturing, using a test
voltage of 1,5 kV.
It is permitted to bridge this insulation with a
capacitor complying with EN 132400:1994,
subclass Y2.
A capacitor classified Y3 according to
EN 132400:1994, may bridge this insulation
under the following conditions:
- the insulation requirements are satisfied by
having a capacitor classified Y3 as defined by
EN 132400, which in addition to the Y3 testing, is
tested with an impulse test of 2,5 kV defined in
EN 60950:2000, 6.2.2.1;
- the additional testing shall be performed on all
the test specimens as described in EN 132400;
- the impulse test of 2,5 kV is to be performed
before the endurance test in EN 132400, in the
sequence of tests as described in EN 132400.
6.1.2.2

S (FI, NO, SE): The exclusions are applicable for No TNV.
PERMANENTLY CONNECTED EQUIPMENT and
PLUGGABLE EQUIPMENT TYPE B and equipment
intended to be used in a RESTRICTED ACCESS
LOCATION where equipotential bonding has been
applied, e.g. in a telecommunication centre, and
which has provision for a permanently connected
PROTECTIVE EARTHING CONDUCTOR and is provided
with instructions for the installation of that
conductor by a service person.

TRF No.:IECEN60950_1B

N/A

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IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Verdict

7.1

S (FI, NO, SE): Requirements according to this
No TNV.
annex, 6.1.2.1 and 6.1.2.2 apply with the term
TELECOMMUNICATION NETWORK in 6.1.2 being
replaced by the term CABLE DISTRIBUTION SYSTEM.

N/A

G.2.1

S (NO): Due to the IT power distribution system
used (see annex V, Fig. V.7), the A.C. MAINS
SUPPLY voltage is considered to be equal to the
line-to-line voltage, and will remain at 230 V in
case of a single earth fault.

Annex G not applied for.

N/A

Annex H

C: Replace the last paragraph of this annex by:

Replaced.

N/A

Replaced.

N/A

At any point 10 cm from the surface of the
operator access area, the dose rate shall not
exceed 1 µSv/h (0,1 mR/h) (see note). Account is
taken of the background level.
Replace the notes as follows:
NOTE These values appear in Directive 96/29/Euratom.

Delete Note 2.
Annex P

C: Replace the text of this annex by:
See annex ZA.

Annex Q

C: Replace the title of IEC 61032 by "Protection of persons and equipment by
enclosures – Probes for verification".

Add the following notes for the standards indicated:
IEC 60127
NOTE Harmonized as EN 60127 (Series) (not modified)
IEC 60269-2-1 NOTE Harmonized as HD 630.2.1 S4:2000 (modified)
IEC 60529
NOTE Harmonized as EN 60529:1991 (not modified)
IEC 61032
NOTE Harmonized as EN 61032:1998 (not modified)
IEC 61140
NOTE Harmonized as EN 61140:2001 (not modified)
ITU-T Recommendation K.31
NOTE in Europe, the suggested document is EN 50083-1.

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IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

Result – Remark

Annex ZA

C: NORMATIVE REFERENCES TO INTERNATIONAL PUBLICATIONS WITH
THEIR RELEVANT EUROPEAN PUBLICATIONS

Verdict
P

This European Standard incorporates, by dated or undated reference, provisions
from other publications. These normative references are cited at the appropriate
places in the text and the publications are listed hereafter. For dated references,
subsequent amendments to or revisions of any of these publications apply to this
European Standard only when incorporated in it by amendment or revision. For
undated references, the latest edition of the publication referred to applies
(including amendments).
NOTE When an international publication has been modified by common modifications, indicated by
(mod), the relevant EN/HD applies.



EN 60065:1998 + corr. June 1999
EN 60073:1996
HD 566 S1:1990
HD 214 S2:1980
HD 611.4.1.S1:1992
1)
HD 21 Series
2)
HD 22 Series
EN 60309 Series
EN 60317-43:1997
EN 60320 Series
HD 384.3 S2:1995
HD 384.4.41 S2:1996
4)
EN 132400:1994
+ A2:1998 + A3:1998 + A4:2001
EN 60417-1
HD 625.1 S1:1996 + corr. Nov. 1996
EN 60695-2-2:1994
EN 60695-2-11:2001




EN 60695-11-10:1999
EN 60695-11-20:1999
EN 60730-1:2000
EN 60825-1:1994 + corr. Febr. 1995 +
A11:1996 + corr. July 1997
EN 60825-2:2000

EN 60851-3:1996
EN 60851-5:1996
EN 60851-6:1996

EN 60990:1999

EN 61965:2001
EN ISO 178:1996
EN ISO 179 Series
EN ISO 180:2000


EN ISO 527 Series

EN ISO 4892 Series
TRF No.:IECEN60950_1B

IEC 60050-151
IEC 60050-195
IEC 60065 (mod):1998
IEC 60073:1996
IEC 60085:1984
IEC 60112:1979
IEC 60216-4-1:1990
IEC 60227 (mod) Series
IEC 60245 (mod) Series
IEC 60309 Series
IEC 60317-43:1997
IEC 60320 (mod) Series
IEC 60364-3 (mod):1993
3)
IEC 60364-4-41 (mod):1992
IEC 60384-14:1993
IEC 60417-1
IEC 60664-1 (mod):1992
IEC 60695-2-2:1991
IEC 60695-2-11:2000
IEC 60695-2-20:1995
IEC 60695-10-2:1995
IEC 60695-11-3:2000
IEC 60695-11-4:2000
IEC 60695-11-10:1999
IEC 60695-11-20:1999
IEC 60730-1:1999 (mod)
IEC 60825-1:1993
IEC 60825-2:2000
IEC 60825-9:1999
IEC 60851-3:1996
IEC 60825-5:1996
IEC 60851-6:1996
IEC 60885-1:1987
IEC 60990:1999
IEC 61058-1:2000
IEC 61965:2000
ISO 178:1993
ISO 179 Series
ISO 180:1993
ISO 261:1998
ISO 262:1998
ISO 527 Series
ISO 386:1984
ISO 4892 Series
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IEC 60950-1 / EN 60950-1

Clause

Requirement – Test

EN ISO 8256:1996

EN ISO 9773:1998



Result – Remark

Verdict

ISO 7000:1989
ISO 8256:1990
ISO 9772:1994
ISO 9773:1998
ITU-T:1988 Recommendation K.17
ITU-T:2000 Recommendation K.21

1) The HD 21 series is related to, but not directly equivalent with the IEC 60227 series
2) The HD 22 series is related to, but not directly equivalent with the IEC 60245 series
3) IEC 60364-4-41:1992 is superseded by IEC 60364-4-41:2001
4) EN 132400, Sectional Specification: Fixed capacitors for electromagnetic interference suppression
and connection to the supply mains (Assessment level D), and its amendments are related to, but not
directly equivalent to IEC 60384-14

TRF No.:IECEN60950_1B

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1.5.1

Page 38 of 73

TABLE: list of critical components

Object/part no.

Manufacturer/
trademark

Type/model

Transformer

Dee Van
Enterprise
Co., Ltd.

90E5W0005-xxH Pri. Winding
(pin 1-A):
90E5W0012-xxH
0.16mmx2px21Ts
(pin A-2):
(xx can be 00–
0.16mmx126Ts
99)

(T1)

Technical data

Standard

Mark(s) of
conformity

Applicable part
of IEC 60950-1
and according
to IEC 60085

Tested with
appliance

Auxiliary primary
winding (pin 4-3):
0.16mmx12Ts
Shield winding:
0.16mmx2px21Ts
Sec. Winding of
90E5W0005-xxH
(pin B-C):
0.35mmx14Ts
Sec. Winding of
90E5W0012-xxH
(pin B-C):
0.20mmx18Ts
Class B
Triple insulated
wire for
secondary
winding

Furukawa
Electric Co.,
Ltd.

TEX-E

Class B

IEC/EN 60950-1 VDE

(Alt.)

Kuo Kuang

SEFU-B

Class B

IEC/EN 60950-1 VDE

(Alt.)

Cosmolink

TIW-M

Class B

IEC/EN 60950-1 VDE

Fusing resistor
(RF1)

TZAI YUAN

KNF

4.7ohm; 1W

Tested with
appliance

(Alt.)

VIS
Electronics
Ltd.

FRT

4.7ohm; 1W

Tested with
appliance

(Alt.)

Jiangsu
Xinyang
Electronics
Ltd.

RF10

4.7ohm; 1W

Tested with
appliance

(Alt.)

Dong Guan
Anson
Electronics
Co., Ltd.

FKN

4.7ohm; 1W

Tested with
appliance

Diode (D1-D4)

Various

Min. 1A; 800V

Storage Cap.
(C1, C2)

Various

1.0-10µF;
Min. 400VDC; 105°C

TRF No.:IECEN60950_1B

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Common Choke Dee Van
(L1)
Enterprise
Co., Ltd.

30D003330-xxH
(xx can be 00–
99)

(Alt.)

Dee Van
Enterprise
Co., Ltd.

30D003400-xxH Pin 1-2:
(xx can be 00-99) 0.12x400.5Ts,
min. 3.0mH,
130°C

Y capacitor
(CY1)

TDK

Max. 2200pF,
IEC/EN 60384AC250V, 25/125/56/B, 14
Y1 type.

VDE

(Alt.)

Murata

Max. 2200pF,
AC250V, 25/125/21,
Y1 type.

IEC/EN 6038414

VDE

(Alt.)

Success

SE, SB

Max. 2200pF,
IEC/EN 60384AC250V, 30/125/56/C, 14
Y1 type.

VDE

(Alt.)

JYA-NAY

Max. 2200pF,
IEC/EN 60384AC250V, 25/125/21/C, 14
Y1 type.

VDE

(Alt.)

Jyh Chung

Max. 2200pF,
IEC/EN 60384AC250V, 25/125/21/C, 14
Y1 type.

VDE

(Alt.)

Welson

Max. 2200pF,
IEC/EN 60384AC250V, 25/125/21/C, 14
Y1 type.

VDE

(Alt)

Chyun Fuh

Max. 2200pF;
AC250V;
25/085/21/C, Y1 type

IEC/EN 6038414

VDE

(Alt)

Jin Yang

X1Y1

Max. 2200pF;
AC250V;
25/085/21/C, Y1 type

IEC/EN 6038414

VDE

(Alt)

Songtian

Max. 2200pF,
IEC/EN 60384AC400V, 25/125/21/C, 14
Y1 type

VDE

Euro-plug

Dee Van
Enterprise
Co., Ltd.

DVE

2.5A; 250VAC

EN 50075

TÜV
Rheinland
(J 2156136)

BS plug

Dee Van
Enterprise
Co., Ltd.

DVE-UK

0.3A; 250VAC

BS 1363

Tested with
appliance

- Pin sleeve of
BS plug

Nan Ya plastic 6410G5
Corp.

PA66, V-0, 130°C

UL E130155

(Optional)

TRF No.:IECEN60950_1B

Pin 1-2:
0.09mmx330Ts;
min. 3mH; 130°C

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Australian plug
portion

Dee Van
DVE-AU
Enterprise Co.,
Ltd.

AC 250V, 0.3A

AS/NZS 3112

Tested with
appliance

- Pin sleeve for
AU plug

Dupont

FR50

PA66, V-0, 130°C

UL E41938

Indian plug

Dee Van
Enterprise
Co., Ltd.

DVE-IN

AC 250V, 0.3A

BS 4573

Tested with
appliance

- Pin holder for
Indian plug

GE Plastic

SE1X

PPE+PS, V-1, 105°C

UL E121562

Enclosure

GE Plastic

SE1X

PPE+PS, V-1, 105°C,
thickness: min.
2.0mm,

UL E121562

Insulation tape

Symbio

35660Y/MY130

130°C

UL E50292

Shrinkable tube

Shenzhen
Woer

RSFR

125°C, VW-1, 600V

UL E203950

(Alt.)

Various

125°C, VW-1, 600V

PCB

WuZhou

WZ-2

V-0 or better;
min. 130°C

UL E170968

(Alt.)

Various

V-0 or better;
min. 130°C

Primary lead
wire

Dong Ju

1007

80°C; min. 24AWG;
VW-1.

UL E189674

(Alt.)

Various

80°C; min. 24AWG;
VW-1

Output cord

Xin Ya
Electronics

2468

80°C, 22AWG Min.
VW-1

UL E170689

(Alt.)

Various

80°C, 22AWG Min.
VW-1

Output cord (if
the part in
enclosure
covered with
heat shrinkable
tube)

Various

60°C, 22AWG Min.
VW-1

Note(s): -1.6.2

TABLE: electrical data (in normal conditions)

Fuse #

Irated
(mA)

U (V)

P (W)

I (mA)

P
Ifuse (mA) Condition/status

Model DSA-5W-05 FEU 050100
RF1

7.4

138

Rated load at 50 Hz

RF1

7.4

140

Rated load at 60 Hz

RF1

200

100

7.4

127

Rated load at 50 Hz

RF1

200

100

7.4

129

Rated load at 60 Hz

TRF No.:IECEN60950_1B

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RF1

200

240

7.9

Rated load at 50 Hz

RF1

200

240

7.9

Rated load at 60 Hz

RF1

264

8.2

Rated load at 50 Hz

RF1

264

8.2

Rated load at 60 Hz

Model DSA-5W-12 FEU 082061
RF1

6.6

118

Rated load at 50 Hz

RF1

6.6

119

Rated load at 60 Hz

RF1

200

100

6.4

108

Rated load at 50 Hz

RF1

200

100

6.5

110

Rated load at 60 Hz

RF1

200

240

7.0

Rated load at 50 Hz

RF1

200

240

7.1

Rated load at 60 Hz

RF1

264

7.4

Rated load at 50 Hz

RF1

264

7.3

Rated load at 60 Hz

Model DSA-5W-12 FEU 120041
RF1

6.5

122

Rated load at 50 Hz

RF1

6.5

125

Rated load at 60 Hz

RF1

200

100

6.5

115

Rated load at 50 Hz

RF1

200

100

6.5

117

Rated load at 60 Hz

RF1

200

240

7.3

Rated load at 50 Hz

RF1

200

240

7.3

Rated load at 60 Hz

RF1

264

7.6

Rated load at 50 Hz

RF1

264

7.6

Rated load at 60 Hz

Note(s):-2.1.1.5

TABLE: max. V, A, VA test

Voltage (rated)
(V)

Current (rated)
(A)

Voltage (max.)
(V)

Current (max.)
(A)

VA (max.)
(VA)

5.9

1.40

5.2

13.4

0.64

6.0

Model DSA-5W-05 FEU 050100
5.0

1.00

Model DSA-5W-12 FEU 120041
12.0

0.41

Note(s):
Test voltage: 264 V
Test frequency: 60 Hz
2.1.1.7
Condition

TABLE: discharge test

τ calculated
(s)

TRF No.:IECEN60950_1B

N/A

τ measured
(s)

t u→ 0V
(s)

Comments

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Page 42 of 73

Note(s): -2.2.2

TABLE: Hazardous voltage measurement

Transformer

Location

max. Voltage
V peak

V d.c.

Pin B-C

48.3

Output

13.6

Voltage Limitation
Component

Model DSA-5W-12 FEU 120041
T1

D8
--

Note(s):
Test voltage: 240 V
Test frequency: 60 Hz
2.2.3

TABLE: SEL voltage measurement

Location

Voltage measured (V)

Comments

Model DSA-5W-12 FEU 120041
Output

Short-circuit D8, circuit protected immediately.

Note(s): -2.4.2

TABLE: limited current circuit measurement

Location

Voltage
(V)

Current
(mA)

Freq.
(Hz)

Limit
(mA)

Comments

4.8

58k

40.6

Model DSA-5W-12 FEU 120041
CY1

9.6

Note(s):
1. Capacitance of CY1: 2200pF
2.5

TABLE: limited power source measurement
Limits

P
Measured

Verdict

≤8

0.56

≤5*Uoc= 67.0

6.0

≤8

0 (unit shut down immediately)

≤5*Uoc= 67.0

0 (unit shut down immediately)

Model DSA-5W-12 FEU 120041
Uoc = 13.4 V (measured under no load conditions)
According to Table 2B (normal condition)
current (in A)
apparent power (in VA)
According to Table 2B (Z1 short-circuited)
current (in A)
apparent power (in VA)
TRF No.:IECEN60950_1B

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According to Table 2B (C10 short-circuited)
current (in A)
apparent power (in VA)

≤8

0 (unit shut down immediately)

≤5*Uoc= 67.0

0 (unit shut down immediately)

≤8

1.40

≤5*Uoc= 29.5

5.2

≤8

0 (unit shut down immediately)

≤5*Uoc= 29.5

0 (unit shut down immediately)

≤8

0.79
(unit shut down immediately)

≤5*Uoc= 29.5

0.53
(unit shut down immediately)

Model DSA-5W-05 FEU 050100
Uoc = 5.9 V (measured under no load conditions)
According to Table 2B (normal condition)
current (in A)
apparent power (in VA)
According to Table 2B (Z1 short-circuited)
current (in A)
apparent power (in VA)

According to Table 2B (C10 short-circuited)
current (in A)
apparent power (in VA)
Note(s): -2.6.3.3

TABLE: ground continue test

Location

N/A

Resistance measured (mΩ) Comments

Note(s): -2.10.2

Table: working voltage measurement

Location

RMS voltage (V)

P
Peak voltage (V) Comments

Model DSA-5W-12 FEU 120041
T1 pin 1-B

122

364

T1 pin 2-B

216

508

T1 pin 4-B

123

326

T1 pin 3-B

129

333

T1 pin 1-C

125

408

T1 pin 2-C

202

496

T1 pin 4-C

125

339

T1 pin 3-C

129

351

Highest working voltage

Note(s):
Test voltage: 240 V
Test frequency: 60 Hz

TRF No.:IECEN60950_1B

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Page 44 of 73

2.10.3 and TABLE: clearance and creepage distance measurements
2.10.4

Clearance cl and creepage
distance dcr at/of:

Up
(V)

U r.m.s.
(V)

Required
cl (mm)

cl
(mm)

Required
dcr (mm)

dcr
(mm)

Unit: primary components
(with 10N) → secondary
components (with 10N)

508

250

4.4

6.8

5.0

7.8

Unit: core of T1 (with 10N) →
secondary components (with
10N)

508

250

4.4

6.6

5.0

6.6

PCB: primary → secondary
traces under transformer

508

250

4.4

7.9

5.0

7.9

PCB: primary → secondary
traces

508

250

4.4

6.7

5.0

6.7

Unit: primary components →
accessible part (outside
enclosure)

508

250

4.4

6.5

5.0

6.5

L, N before fusing resistor

420

250

1.5

2.7

2.5

2.7

Two pins of fusing resistor

420

250

1.5

2.7

2.5

2.7

Note(s):
1)

Functional insulation shorted, see sub-clause 5.3.4.

Reinforced insulation provided between primary and secondary winding.

2.10.5

TABLE: distance through insulation measurements

Distance through insulation di at/of:

U r.m.s.
(V)

Test voltage
(V)

Required di
(mm)

di
(mm)

250

3000

0.4

2.0

Enclosure material (reinforced insulation)
Note(s):
1.) Further details are provided in table 1.5.1.
2.) Test voltages are a.c.
4.5.1

TABLE: temperature rise measurements

test voltage (V) ..................................................... :

a): 90 V, 60 Hz
b): 264 V, 50 Hz



t1 (°C) .................................................................. :

40.0



t2 (°C) .................................................................. :

40.0


T (°C)

Rise ∆T of part/at:
Test voltage:

allowed Tmax (°C)

Plug portion

47.5

45.8

T1 winding

98.8

97.1

110

T1 core

97.4

94.8

110

Model DSA-5W-05 FEU 050100

TRF No.:IECEN60950_1B

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Y capacitor CY1

74.9

70.3

Linear Filter L1 winding

78.2

83.4

130

PCB under Q1

105.5

107.5

130

PCB under D8

91.3

89.5

130

Electrolytic Capacitor C2

87.0

88.5

105

Primary lead wire

60.0

59.3

Output cord

59.4

56.7

Enclosure (inside)

64.5

62.3

105

Enclosure (outside)

55.9

53.6

Ambient

40.0

Plug portion

45.7

44.8

T1 winding

102.3

88.7

110

T1 core

100.1

86.3

110

Y capacitor CY1

76.6

66.6

Linear Filter L1 winding

77.1

71.2

130

PCB under Q1

112.5

89.3

130

PCB under D8

88.9

79.7

130

Electrolytic Capacitor C2

97.1

81.5

105

Primary lead wire

60.1

55.8

Output cord

65.5

59.5

Enclosure (inside)

64.1

57.9

105

Enclosure (outside)

58.1

53.4

Ambient

40.0

Plug portion

46.8

46.4

T1 winding

98.9

95.7

110

T1 core

96.5

92.1

110

Y capacitor CY1

70.7

67.3

Linear Filter L1 winding

75.9

75.7

130

PCB under Q1

105.8

91.6

130

PCB under D8

78.0

76.0

130

Electrolytic Capacitor C2

87.9

80.8

105

Primary lead wire

67.2

68.0

Output cord

60.9

59.0

Enclosure (inside)

59.5

56.9

105

Enclosure (outside)

55.3

53.1

Model DSA-5W-12 FEU 082061

Model DSA-5W-12 FEU 120041

TRF No.:IECEN60950_1B

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Page 46 of 73

Ambient

40.0

R1
(Ω)

R2
(Ω)

T
(°C)

Allowed
Tmax (°C)

insulation
class

Temperature rise ∆T of winding:

Note(s):
The temperatures were measured under worst case normal mode defined in 1.2.2.1 and as described in subclause 1.6.2 and at voltages as described above.
With a rated maximum ambient temperature of 40 °C, the maximum temperature rises are calculated as
follows:
Winding components providing safety isolation:
- Class B for T1
→ Tmax = 120°C-10°C = 110°C (thermocouple method)
Components with maximum absolute temperature of:
- Electrolytic Capacitor
105 °C
- Y Capacitor
85 °C
- PCB
130 °C
- L1 winding
130 °C
- Output cord
80 °C
- Primary lead wire
105 °C
- enclosure (inside)
105 °C
Operator touchable surface with maximum temperature rise of:
- 95°C
4.5.2

TABLE: ball pressure test of thermoplastic parts

allowed impression diameter (mm) ................. : ≤ 2 mm



Part

Test temperature
(°C)

Impression diameter
(mm)

Pin sleeving material for BS plug

125

1.0

Plug holder material for Euro-plug

125

1.0

Plug holder material for Indian plug

125

1.0

Pin sleeving material of Australian plug

125

1.0

PCB

125

1.0

Enclosure

125

1.3

Note(s):
1. The bobbin material of T1 and L1 is phenolic, no test is required.
4.6.1, 4.6.2 Table: enclosure openings

Location

Size (mm)

Comments

Bottom

No openings

Sides

No openings

Top

No openings

Note(s):-TRF No.:IECEN60950_1B

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4.7

Page 47 of 73

Table: resistance to fire

Part

N/A

Manufacturer of material

Type of material

Thickness
(mm)

Flammability
class

Note(s): refer to table 1.5.1 for details.
5.1.6

TABLE: touch current measurement

Condition

L→ terminal A
(mA)

N → terminal A
(mA)

Limit
(mA)

Comments

Model DSA-5W-12 FEU 120041
System ON

0.18

0.25

Test location: o/p connector

System ON

0.01

0.25

Test location: enclosure wrapped with
metal foil

Note(s):
Test voltage: 264 V
Test frequency: 60 Hz
5.2

TABLE: electric strength tests and impulse tests

Test voltage applied between:

Test voltage (V)

Breakdown

Unit:

primary circuit to secondary circuit

4240 V d.c.

Unit:

primary circuit to accessible enclosure

3000 V a.c.

T1:

primary winding to secondary winding

3000 V a.c.

T1:

core to secondary winding

3000 V a.c.

Note(s): -5.3

TABLE: fault condition tests

ambient temperature (°C) ................................. :

40°C if not specified



model/type of power supply .............................. :



manufacturer of power supply .......................... :

Dee Van



rated markings of power supply ....................... :

See model list



No. Component no.

Fault

Test
voltage (V)

Test
time

Fuse
Fuse
Result
no. current (A)

Model DSA-5W-12 FEU 120041

TRF No.:IECEN60950_1B

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Page 48 of 73
s-c

264

RF1

With fusible resistor type KNF:
RF1 opened immediately, no
hazards.
With fusible resistor type FKN:
RF1 opened immediately, no
hazards.
With fusible resistor type RF10:
RF1 opened immediately, no
hazards.
With fusible resistor type FRT:
RF1 opened immediately, D3
damaged, no hazards.
Repeated 10 times each on
these fusible resistors and got
same result.

s-c

264

RF1

With fusible resistor type KNF:
RF1 opened immediately, L1
damaged, no hazards.
With fusible resistor type FKN:
RF1 opened immediately, no
hazards.
With fusible resistor type RF10:
RF1 opened immediately, no
hazards.
With fusible resistor type FRT:
RF1 opened immediately, D1,
D3 damaged, no hazards
Repeated 10 times each on
these fusible resistors and got
same result.

s-c

264

RF1

s-c

264

30 min

RF1

0.05

Unit work normally, no hazards.

s-c

264

30 min

RF1

0.06

Unit work normally, no hazards.

TRF No.:IECEN60950_1B

TRF originator: SGS Fimko

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Q1 pin c-e

Page 49 of 73
s-c

264

RF1

With fusible resistor type KNF:
RF1 opened immediately, L1
damaged, no hazards.
With fusible resistor type FKN:
RF1 opened immediately, no
hazards.
With fusible resistor type RF10:
RF1 opened immediately, no
hazards.
With fusible resistor type FRT:
RF1 opened immediately, no
hazards.
Repeated 10 times each on
these fusible resistors and got
same result.

Q1 pin c-b

s-c

264

RF1

With fusible resistor type KNF:
RF1 opened immediately, L1,
R9, Q1, Z1, D7 damaged, no
hazards.
With fusible resistor type FKN:
RF1 opened immediately, no
hazards.
With fusible resistor type RF10:
RF1 opened immediately, no
hazards.
With fusible resistor type FRT:
RF1 opened immediately, no
hazards
Repeated 10 times each on
these fusible resistors and got
same result.

Q1 pin b-e

s-c

264

5 min

RF1

0.01

Unit shut down immediately, no
hazards.

s-c

264

5 min

RF1

0.01

Unit shut down immediately, no
hazards.

s-c

264

30 min

RF1

0.06

Unit worked normally, no
hazards.

s-c

264

5 min

RF1

0.01

Unit shut down immediately, no
hazards.

TRF No.:IECEN60950_1B

TRF originator: SGS Fimko

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Page 50 of 73
s-c

264

RF1

With fusible resistor type KNF:
RF1 opened immediately, L1,
R9, Q1, Z1 damaged, no
hazards.
With fusible resistor type FKN:
RF1 opened immediately,Q1
damaged, no hazards.
With fusible resistor type RF10:
RF1 opened immediately, Q1
damaged, no hazards.
With fusible resistor type FRT:
RF1 opened immediately, Q1
damaged, no hazards.
Repeated 10 times each on
these fusible resistors and got
same result.

s-c

264

RF1

With fusible resistor type KNF:
RF1 opened immediately, L1,
R9, Q1, Q2, Z1, D7, D8
damaged, no hazards.
With fusible resistor type FKN:
RF1 opened immediately, Q1
damaged, no hazards.
With fusible resistor type RF10:
RF1 opened immediately, Q1
damaged, no hazards.
With fusible resistor type FRT:
RF1 opened immediately, Q1
damaged, no hazards.
Repeated 10 times each on
these fusible resistors and got
same result.

C10

s-c

264

30 min

RF1

0.23

Unit shut down immediately, no
hazards.

T1 pin 3-4

s-c

264

5 min

RF1

0.02

Unit shutdown immediately, no
hazards.

T1 pin B-C

s-c

264

5 min

RF1

0.01

Unit shut down immediately, no
hazards.

s-c

264

5 min

RF1

0.01

Unit shut down immediately, no
hazards.

s-c

264

5 min

RF1

0.01

Unit shutdown immediately, no
hazards.

Output

o-l

264

RF1

0.07

The output overload to 0.64A,
T1 coil = 100°C at ambient
temperature 23°C, no hazards.

Output

s-c

264

5 min

RF1

0.01

Unit shut down immediately, no
hazards.

264

1.8 h

RF1

0.08

The output overload to 1.40A,
T1 coil = 102°C at ambient
temperature 23°C, no hazards.

Model DSA-5W-05 FEU 050100
21

Output

TRF No.:IECEN60950_1B

o-l

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22

Output

Page 51 of 73
s-c

264

5 min

RF1

0.01

Unit shut down immediately, no
hazards.

Model DSA-5W-12 FEU 082061
23

Output

o-l

264

RF1

0.06

The output overload to 0.82A,
T1 coil = 102°C at ambient
temperature 24°C, no hazards.

Output

s-c

264

5 min

RF1

0.01

Unit shut down immediately, no
hazards.

Note(s): - In fault column, where s-c=short-circuited, o-l= over-loaded, o-c= open-circuited.
C.2

Safety isolation transformer

Construction details:
Transformer part name: T1
Manufacturer: see table 1.5.1
Type:

see table 1.5.1

Recurring peak voltage

508 Vpeak

Required clearance for reinforced
insulation (from table 2H and 2J)

4.4 mm

Effective voltage rms

250 Vrms

Required creepage distance for reinforced
insulation (from table 2L)

5.0 mm

Measured min. creepage distance
Location

inside (mm)

outside (mm)

prim-sec

TIW used

8.6

core-sec

TIW used

8.6

prim-core

prim-sec

TIW used

8.6

core-sec

TIW used

8.6

prim-core

Measured min. clearances

Construction:
Concentric windings on EF-16 size bobbin. 2 layer of insulation tape between primary (enamelled copper wire)
and secondary windings (triple insulation wire), 2 layers on outer winding. Winding ends additionally fixed with
tape, outer winding is secondary.
Pin numbers
TRF No.:IECEN60950_1B

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Prim.

1→2; 4→3

Sec.

B→C

Bobbin
Material

Hitachi, Phenolic, type CP-J-8800

Thickness

1.0 mm

Electric strength test
With AC 3000V after humidity treatment
Result

TRF No.:IECEN60950_1B

Pass

TRF originator: SGS Fimko

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Page 53 of 73
National Differences

Clause

Result – Remark

Requirement − Test

APPENDIX Australian National Differences according to CB Bulletin No. 112A, December
2006 (AS/NZS 60950.1:2003)

Verdict
P

(IEC Publication 60950-1:2001)
EXPLANATION FOR ABBREVIATIONS
P=Pass, F=Fail, N/A=Not applicable. Placed in the column to the right.
Annex ZZ Variations
1.2

Between the definitions for "Person, service" and
"Range, rated frequency" insert the following:
Potential ignition source

1.2.12.15

Inserted.

1.2.12.201

After the definition of 1.2.12.15, add the following: Added.

1.2.12.201 Potential ignition source:
Possible fault which can start a fire if the opencircuit voltage measured across an interruption or
faulty contact exceeds a value of 50 V (peak) a.c.
or d.c. and the product of the peak value of this
voltage and the measured r.m.s. current under
normal operating conditions exceeds 15 VA.
Such a faulty contact or interruption in an
electrical connection includes those which may
occur in conductive patterns on printed boards.
NOTE 201: An electronic protection circuit may be
used to prevent such a fault from becoming a
potential ignition source.
NOTE 202: This definition is from AS/NZS
60065:2003.
1.5.1

Add the following to the end of first paragraph:

Added.

"or the relevant Australian/New Zealand
Standard."
1.5.2

Add the following to the end of first and third dash Added and see plug test
items:
report.

"or the relevant Australian/New Zealand
Standard."
2.1

Delete the Note.

Deleted

3.2.3

Delete Note 2.

Deleted

N/A

3.2.5

Modify Table 3B as follows:

Replaced.

N/A

Rated current of
equipment A

Nominal
crosssectional
2
area mm

AWG or kcmil
(cross-sectional
2
area in mm )
see note 2

Over 0.2 up to
and including 3

0.5

18 [0.8]

Over 3 up to and
including 7.5

0.75

16 [1.3]

Over 7.5 up to
and including 10

(0.75) 1.00

16 [1.3]

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Page 54 of 73
National Differences

Clause

Result – Remark

Requirement − Test
Over 10 up to
and including 16

(1.0) 1.5

Verdict

14 [2]

Replace footnote 1) with the following:
1)

This nominal cross-sectional area is only
allowed for Class II appliances if the length of the
power supply cord, measured between the point
where the cord, or cord guard, enters the
appliances, and the entry to the plug does not
exceed 2 m (0.5 mm² three-core supply flexible
cords are not permitted; see AS/NZS 3191).
Delete Note 1.
4.3.6

Replace paragraph three with:

Replaced.

N/A

Equipment with a plug portion, suitable for
insertion into a 10 A 3-pin flat-pin socket-outlet
complying with AS/NZS 3112, shall comply with
the requirements in AS/NZS 3112 for equipment
with integral pins for insertion into socket-outlets.
4.3.13.5

Add the following to the end of the first paragraph: Added.

", or AS/NZS 2211.1"
4.7

Add the following paragraph:

Added.

For alternative tests refer to clause 4.7.201.
4.7.201

Add the following after clause 4.7.3.6:
4.7.201 Resistance to fire - Alternative tests

4.7.201.1

General

Enclosure, PCB, bobbin, pin
Parts of non-metallic material shall be resistant to sleeving
ignition and spread of fire.
This requirement does not apply to decorative
trims, knobs and other parts unlikely to be ignited
or to propagate flames originating from inside the
apparatus, or the following:
(a) Components that are contained in an
enclosure having a flammability category of
FV-0 according to AS/NSZ 4695.707 and
having openings only for the connecting wires
filling the openings completely, and for the
ventilation not exceeding 1 mm in width
regardless of the length.
(b) The following parts which would contribute
negligible fuel to a fire:
-

small mechanical parts, the mass of which
does not exceed 4 g, such as mounting
parts, gears, cams, belts and bearings;

small electrical components, such as
capacitors with a volume not exceeding
3
1750 mm , integrated circuits, transistors and
optocoupler packages, if these components
are mounted on material flammability
category FV-1 or better according to AS/NZS

Australian National Differences according to CB Bulletin No. CB Bulletin No. 112A, December 2006

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Page 55 of 73
National Differences

Clause

Requirement − Test

Result – Remark

Verdict

4695.707
NOTE - In considering how to minimize
propagation of fire and what “small parts” are,
account should be taken of the cumulative effect
of small parts adjacent to each other for the
possible effect of propagating fire from one part to
another.
Compliance is checked by tests of 4.7.201.2,
4.7.201.3, 4.7.201.4 and 4.7.201.5.
For the base materials of printed boards,
compliance is checked by the test of 4.7.201.5.
The tests shall be carried out on parts of nonmetallic material, which have been removed from
the apparatus. When the glow-wire test is carried
out, the parts shall be placed in the same
orientation, as they would be in normal use.
These tests are not carried out on internal wiring.
4.7.201.2

Parts of non-metallic material are subjected to
glow wire test of AS/NZS 4695.2.11, which is
carried out at 550 °C.

Enclosure

PCB, bobbin, Pin sleeve

Parts for which the glow-wire test cannot be
carried out, such as those made of soft or foamy
material, shall meet the requirements specified in
ISO 9772 for category FH-3 material. The glowwire test shall be not carried out on parts of
materials classified at least FH-3 according to
ISO 9772 provided that the sample was not
thicker than the relevant part.
4.7.201.3

Testing of insulating materials
Parts of insulating materials supporting potential
ignition sources shall be subject to the glow-wire
test of AN/NZS 4695.2.11, which is carried out at
750 °C.
The test shall be also carried out on other parts of
insulating material which are within a distance of
3 mm of the connection.
NOTE - Contacts in components such as switch
contacts are considered to be connections.
For parts, which withstand the glow-wire test but
produce a flame, other parts above the
connection within the envelope of a vertical
cylinder having a diameter of 20 mm and a height
of 50 mm shall be subjected to the needle-flame
test. However, parts shielded by a barrier which
meets the needle-flame test shall not be tested.
The needle-flame test shall be made in
accordance with AS/NZS 4695.2.2 with the
following modifications:
5 Severities
Replace with:

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Page 56 of 73
National Differences

Clause

Requirement − Test

Result – Remark

Verdict

The duration of application of the test flame shall
be 30 s
1 s.
8 Test procedure
8.2 Modification:
Replace the first sentence with:
The specimen shall be arranged so that the flame
can be applied to a vertical or horizontal edge as
shown in the examples of figure 1.
8.4 Modification:
The first paragraph does not apply.
Addition:
If possible, the flame shall be applied at least
10 mm from a corner.
8.5 Replacement:
The test shall be made on one specimen. If the
specimen does not withstand the test, the test
may be repeated on two further specimens, both
of which shall then withstand the test.
10 Evaluation of test results
Replace with:
The duration of burning (tb) shall not exceed 30 s.
However, for printed circuit boards, it shall not
exceed 15 s.
The needle-flame test shall not be carried out on
parts of material classified as V-0 or V-1
according to IEC 60695-11-10, provided that the
sample tested was not thicker than the relevant
part.
4.7.201.4

Testing in the event of non-extinguishing material Added.
If parts, other than enclosures, do not withstand
the glow-wire tests of 4.7.201.3, by failure to
extinguish within 30 s after the removal of the
glow-wire tip, the needle-flame test detailed in
4.7.201.3 is made on all parts of non-metallic
material which are within a distance of 50 mm or
which are likely to be impinged upon by flame
during the tests of 4.7.201.3. Parts shielded by a
separate barrier which meets the needle-flame
test need not to be tested.
NOTE 1 - If the enclosure does not withstand the
glow-wire test the equipment is considered to
have failed to meet the requirement of clause
4.7.201 without the need for consequential
testing.
NOTE 2 - If other parts do not withstand the glowwire test due to ignition of the tissue paper and if
this indicates that burring or glowing particles can

Australian National Differences according to CB Bulletin No. CB Bulletin No. 112A, December 2006

N/A

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Page 57 of 73
National Differences

Clause

Requirement − Test

Result – Remark

Verdict

fall onto an external surface underneath the
equipment, the equipment is considered to have
failed to meet the requirement of clause 4.7.201
without the need for consequential testing.
NOTE 3 - Parts likely to be impinged upon by the
flame are considered to be those within the
envelope of a vertical cylinder having a radius of
10 mm and a height equal to the height of the
flame, positioned above the point of the material
supporting in contact with or in close proximity to
connections.
4.7.201.5

Testing of printed boards

Added.

The base material of printed boards is subjected
to needle-flame test to Clause 4.7.201.3. The
flame is applied to the edge of the board where
the heat sink effect is lowest when the board is
positioned as in normal use. The flame shall not
be applied to an edge, consisting of broken
perforations, unless the edge is less than 3 mm
for a potential ignition source.
The test is not carried out if the –
- Printed board does not carry any potential
ignition source;
- Base material of printed boards, on which the
available apparent power at a connection
exceeds 15 VA operating at a voltage
exceeding 50 V and equal or less than 400 V
(peak) a.c. or d.c. under normal operating
conditions, is of flammability category FV-1 or
better according to AS/NZS 4695.707, or the
printed boards are protected by an enclosure
meeting the flammability category FV-0
according to AS/NZS 4695.707, or made of
metal, having openings only for connecting
wires which fill the opening completely, or
- Base material of printed boards, on which the
available apparatus power at a connection
exceeds 15 VA operating at a voltage
exceeding 400 V (peak) a.c. or d.c. under
normal operating conditions, and base material
printed boards supporting spark gaps which
provide protection against overvoltages, is of
flammability category FV-0 according to
AS/NSZ 4695.707 or the printed boards are
contained in a metal enclosure, having
openings only for connecting wires fill the
openings completely.
Compliance is determined using the smallest
thickness of the material.
NOTE - Available apparent power is the
maximum apparent power, which can be drawn
from the supplying circuit through a resistive load
whose value is chosen to maximise the apparent
power for more than 2 min when the circuit
Australian National Differences according to CB Bulletin No. CB Bulletin No. 112A, December 2006

N/A

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Page 58 of 73
National Differences

Clause

Result – Remark

Requirement − Test

Verdict

supplied is disconnected.
6.2.2

Add the following after the first paragraph:

No TNV.

N/A

No TNV.

N/A

No TNV.

N/A

In Australia (this variation does not apply in New
Zealand), compliance with 6.2.2 is checked by the
tests of both 6.2.2.1 and 6.2.2.2.
Delete the note.
6.2.2.1

Delete Note 2.
Add the following after the first paragraph:
In Australia (this variation does not apply in New
Zealand), the electrical separation is subjected to
10 impulses of alternating polarity, using the
impulse test generator of annex N for 10/700 µs
impulses. The interval between successive
impulses is 60 s and the initial voltage, Uc, is:
- for 6.2.1 a):
7.0 kV for hand-held telephones and for
headsets and 2.5 kV for other equipment; and
- for 6.2.1b) and 6.2.1c):
1.5 kV.
NOTE 201 - The 7 kV impulse simulates lightning
surges on typical rural and semi-rural network
lines.
NOTE 202 – The 2.5 kV impulse for 6.2.1a) was
chosen to ensure adequacy of the insulation
concerned and does not necessarily simulate
likely overvoltages.

6.2.2.2

Delete the note.
Add the following after the second paragraph:
In Australia (this variation does not apply in New
Zealand), the a.c. test voltage is:
- for 6.2.1a):

3 kV; and

- for 6.2.1b) and 6.2.1c):

1.5 kV.

NOTE 201 – Where there are capacitors across
the insulation under test, it is recommended that
d.c. test voltages are used.
NOTE 202 – The 3 kV and 1.5 kV values have
been determined considering the low frequency
induced voltages from the power supply
distribution system.
Annex P

Add the following Normative References to Annex Added.
P:
IEC 60065, Audio, Video and similar electronic
apparatus - Safety requirements
AS/NZS 3112, Approval and test specification Plugs and socket-outlets
AS/NZS 3191, Approval and test specification -

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Page 59 of 73
National Differences

Clause

Requirement − Test

Result – Remark

Electric flexible cords
AS/NZS 4695.707, Fire hazard testing of
electrotechnical products - Methods of test for the
determination of the flammability of solid electrical
insulating materials when exposed to an igniting
source

Australian National Differences according to CB Bulletin No. CB Bulletin No. 112A, December 2006

Verdict

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Page 60 of 73
EN 50075 (Partial)

Clause

Requirement − Test

Result – Remark

Verdict

Dimensions

Plug shall comply with Standard Sheet 1

Between two pins (pin base)

18.0 – 19.2 mm

18.4 mm

Between two pins (pin top)

17.0 – 18.0 mm

17.3 mm

Diameter of pin (metallic part)

4±

4.0 mm

Diameter of pin (pin base)

max. 4.0 mm

3.8 mm

Diameter of pin (middle part)

max. 3.8 mm

3.5 mm

0.06

± 0.5

19.4 mm

+ 1.0

10.3 mm

Pin length

Length of pin except metal part

Shape of pin top

Round shape

± 0.7

35.5 mm

0.7

13.8 mm

26.4 mm

Length of plug base

35.3

Width of plug base

13.7±

0.5

Diagonal dimension of plug base <26.1± mm
within a distance of 18mm
0.5
<26.1± mm

26.3 mm

Note: Only the dimensions of Euro-plug have been measured and recorded since it is a certified plug (see
table 1.5.1).

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Page 61 of 73
BS 1363 (Partial)

Clause

Requirement − Test

Result – Remark

Verdict

Construction

12.1

Disposition of the pins is same as fig. 4

12.2

Plugs shall comply with fig. 4

Disposition of pins

Between E and left plane

max. 25.37 mm

24.30 mm

Between E and right plane

max. 25.37 mm

24.32 mm

Between E and L

11.05~11.18mm

11.08 mm

Between E and N

11.05~11.18mm

11.08 mm

Between L or N and top plane

max. 34.6mm

27.74 mm

Between E and L, N

22.10~22.36mm

22.30 mm

Radius of top right corner

min. 15mm

15.50 mm

Radius of top left corner

min. 15mm

15.50 mm

Shape of earth pin

Length

22.23~23.23mm

22.60 mm

Width

7.80~8.05mm

8.00 mm

Thickness

3.90~4.05mm

4.00 mm

Length of chamfer

1.35~1.85mm

1.68 mm

Angle of chamfer

58°~62°

59 °

Shape of L and N pin

Length

17.2~18.2mm

17.80 mm

Width

6.22~6.48mm

6.30 mm

Thickness

3.90~4.05mm

4.00 mm

Length of insulating material

max. 9.5mm

9.36 mm

Length of conductive material

max. 9.2mm

8.44 mm

Length of chamfer

1.35~1.85mm

1.56 mm

Angle of chamfer

58°~62°

59 °

Maintenance of these dimensions not rely on the
terminal screws

The plug portion should enter the gauge fully with a Complied, sample was entered
force less than 10N was applied to the centre of
into the gauge fully with a force
the sample at right angle.
of 10N.

12.3

No part of a line or neutral pin shall be less than
9,5mm from the periphery of the plug measured
along the engagement surface.

Complied, both line and neutral
pin are measured larger that
9.5mm

12.9

Plug pins were constructed of brass

Complied.

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BS 1363 (Partial)

Clause

Requirement − Test

Result – Remark

12.9.1

Exposed surface of plug pins were smooth and
free from burrs or sharp edges and other
irregularities, which could cause damage or
excessive wear to sockets or shutters.

Complied.

12.9.4

The adaptor plug pins were tested as specified in
the standard.

Complied. After being
subjected to a forced of 1100N,
the pin portion could fit the
relevant gauge.

12.9.5

The adaptor plug pins were tested as specified in
the standard.

Complied. After being
subjected to 5000 insertions
and withdraws, the shutters of
the socket-outlet can operate
satisfactorily and the socket
contact is safely shielded.

12.9.6

Each pin of the adaptor was subjected to a torque
of 1Nm for 60s as specified in the standard.

Complied. After the test, the pin
portion could fit the relevant
gauge.

12.11

The adaptors were tested as specified in the
standard. After being placed in an oven at 70°C for
1 hour, each pin of the samples was subjected for
60 sec. to a pull of 100N in the oven.

Complied. After the above test,
no plug pin was detached and
the plug pins could fit the
relevant gauge.

12.12

The degree of flexibility of mounting of the plug
pins was checked according to 12.12.1

Complied. During the test, no
declination was observed to the
plug pins (limit: Max. 3° 30’).

12.16

Line and neutral plug pin shall be fitted with
insulating sleeves. The dimensions of the pin and
sleeve shall fall within the specific limit.

Complied. Both line and neutral
pins were fitted with insulating
sleeves.

12.17.1

Plug pin sleeve shall be compliance with 12.17.2 to Complied.
12.17.4

12.17.2

Electric strength test applied between the metal
part of plug pin and the sleeve (1250±30V)

Complied. No breakdown and
flashover occur.

12.17.3

Abrasion test for plug pin sleeve

Complied. After the test, the
sleeves showed no damage
that impaired further use and
could satisfy the electric
strength test in 12.17.2

Complied. After the tests, the
thicknesses of sleeve of plug
pins (line and neutral pins)
remaining at the impression
point were reduced by less
than 5%.

The plug pin sleeves were subjected to 20000
movements of abrasion as specified in the
standard.
12.17.4

Resistance to deformation
The plug pins with sleeves were placed in a
heating cabinet at 200°C and tested according to
the standard for 120min.

Notes: clause 12.4, 12.5, 12.6, 12.7, 12.8, 12.9.2, 12.9.3, 12.10, 12.13, 12.14, 12.15 were not
applicable.

Verdict

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Page 63 of 73
AS/NZS 3112 (Partial)

Clause

Requirement − Test

Scope
This Appendix applies to only the plug portion of
equipment with integral pins and shall be read in
conjunction with section 2 contained in the body
of this standard. Where the term ‘plug’ is used in
section 2 it shall be taken to mean the plug
portion of equipment with integral pins.

Result – Remark

Verdict
P

Plug portion with integrated pins

Requirements for plug portion

J2.1

definition

J2.2

requirments

J2.2.1

Plug pins of plug portions
Material for pins

J2.2.2

See below.

P
P

Copper alloy containing 62%
copper.

Assembly of pins

Form of pin

Insulation of plug pin

Ratings and dimensions for low voltage plug
portions

Comply with 10A 250V two-pin
plug.

General

P
P

Compliance with dimensional requirements of
Figure 2.1

See attached dimension table.

J2.2.3

Internal connections for plug portions

No earthing pin.

N/A

J2.2.4

Arrangement of earthing connections for plug
portions

No earthing pin.

N/A

J2.2.5

Configuration of plug portions

J2.2.6.1

General

J2.2.6.2

High voltage test (3112.2.13.3)

The plug shall withstand without failure an a. c.
voltage of the value indicated in Table 2.3,
applied between the parts set our in Items (a)
and (c) of Clause 2.13.2 for 1 min in each case.

The plug shall further withstand, without failure,
a voltage of 3500 V a. c. applied between the
parts set out in Items (b) and (d) of Clause
2.13.2 for 1 min in each case.

The insulation of insulated pin plugs shall
withstand a voltage of 1 250V a. c. for 1 min
applied in accordance with Clause 2.13.2(e).

Mechanical strength of pin tests

J2.2.6.3

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Page 64 of 73
AS/NZS 3112 (Partial)

Clause

Requirement − Test

J2.2.6.3.1

Tumbling barrel test (3112.2.13.7.1)

The tumbling barrel test is applied to determine
the mechanical strength of the plug pins.

Three samples which have not been subjected
to any previous test are tested to the
requirements of Clause 2.13.7 however, the test
is modified for plug portions of equipment with
integral pins as follows:

A sample of equipment with integral pins is
dropped –

Weight: 75g.
a) 500 times if the mass of the specimen does
not exceed 250 g. The pins being straightened
500 times.
after 100 drops and at the completion of the test
to pass through the appropriate gauge of Figure
A1, B1 or F1; and

b) 250 times if the mass of the specimen
exceeds 250 g. The pins being straightened
after 25 drops and at the completion of the test
to pass through the appropriate gauge of Figure
A1, B1 or F1
J2.2.6.3.2

Result – Remark

Verdict

N/A

Pin bending test

The pins of the plug portion of three samples
not subjected to any previous tests shall be
tested for compliance with the pin bending test
of clause 2.13.7.2.

All flat-pins of plugs rated up to and including 15
A shall be subjected to a pin bending test.

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Page 65 of 73
AS/NZS 3112 (Partial)

Clause

Requirement − Test
Three sample plugs not subjected to any
previous tests shall be tested as follows:
Pins of assembled plugs shall be tested by
clamping the plug in a rigid holding block and
applying a bending force, as shown in Figure
2.8, to the pin under test.
The pins shall be straight at the beginning of the
test. If there is any doubt about the straightness
of the pin, it shall be checked by the appropriate
plug gauge shown in Appendices A, B or F.
The point of application of the force shall be 14
±0.5 mm from the face of the plug.
The direction of the force shall be along a line
parallel to the face of the plug.
Active and neutral pins shall be forced towards
the centroid of the plug and then back to the
starting point.
On the first sample plug, any earth pin shall be
forced but in one direction only and then back to
the starting point.On the second sample plug,
any earth pin shall be forced in the opposite
direction to that used for testing the first sample
plug. On the third sample plug, any earth pin
shall be forced in the direction that gave the
least favourable result during testing of the first
two sample plugs.
NOTE: This is intended to simulate damage that
may occur when a plug is walked on and bent
pins are straightened.
The distance moved from the point of
application shall be 7.5+/-0.3 mm, and then the
pin shall be forced back to the starting point.
Any ’spring-back'is ignored
NOTE: ’Spring-back'means that the pin is
allowed to move back to a position less than the
travel distance, when the force is removed.
The travel from the starting point, to the end
point (7,5 mm), and back to the starting point is
one cycle (i.e. one cycle is two separate
movements).
The speed of deflections shall be a maximum of
50 mm/s, without intentional delay between
consecutive movements within each cycle.
The interval between successive cycles shall be
a minimum of 10 s.
The duration of one cycle shall be a maximum
of 60 s.
The pins shall be tested for 20 complete cycles.
After the tests the pins shall be inspected with
normal or corrected to normal vision.

Result – Remark

Verdict
P

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Page 66 of 73
AS/NZS 3112 (Partial)

Clause

Requirement − Test

Result – Remark

The pin shall not be broken off.

Verdict
P

NOTE: Cracking of the pin, less than full
thickness, is not deemed to be broken off.
If in doubt pins shall be disassembled from the
plug and any insulation removed,
NOTE: In some cases the break may be below
the face of the plug or the insulation may hold
the broken pieces together, retaining electrical
contact.
J2.2.6.4

Temperature rise test (3112.2.13.8)

The test current have been
specified and tested with the
integral adaptor.

2.13.8 Temperature rise test
Plugs shall be so constructed that they comply
with the following temperature rise test:

P
Non-rewireable plugs

a) Non-rewireable plugs are tested as
delivered (specially prepared sample
with access to terminals for
temperature measurement).
b) Rewireable plugs are fitted with
polyvinyl chloride flexible cords with
conductors having the minimum crosssectional area specified in the
manufacturers instructions.
The terminal screws or nuts are tightened with a No screws or nuts used.
torque equal to two-thirds of that specified in
test No.5.

N/A

NOTE: To ensure normal cooling of the
terminals, the conductors connected to plugs
should have a length of at least 1 m.
Direct plug-in equipment.

N/A

Direct plug-in equipment.
The fixed socket outlet shall be mounted in an
appropriate metal-wall box installed in a draught
free position, and fitted with PVC insulated
conductors at least 2.5 m long, having nominal
cross-sectional areas as shown in Table 3.4.

N/A

Direct plug-in equipment.

N/A

The test socket shall consist of a fixed socket
outlet of a type complying with this Standard.
NOTE: In the case of a dispute, the test should
be repeated using a new socket outlet.

The cables supplying the socket outlet shall be
enclosed for a distance of 1 m in conduit
terminated at the wall box.
The plug is inserted into the socket outlet and
an alternating current of 1.1 times rated current
is passed for 1 h.

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Page 67 of 73
AS/NZS 3112 (Partial)

Clause

Requirement − Test

Result – Remark

The temperature of the flexible cord terminal is Direct plug-in equipment.
determined by means of melting particles,
colour changing indicators or thermocouples, so
chosen and positioned that they have negligible
effect on the temperature being determined.

J2.2.6.5

Verdict
N/A

The temperature rise of the terminals shall not
exceed 45 K.

Securement of pins (3112.2.13.9)

Movement of pins (2.13.9.1)

Plugs shall be tested for pin movement by
clamping the pin or pins not under test in a rigid
holding block positioned 5 ±0.5 mm from the
plug face and applying a force of 18±1 N to the
pin under test. The design of the block shall be
such that the pin under test shall not come into
contact with the block during the test.

Except for non-rewireable plugs, the test shall
be carried out without a cord attached to the
plug, and with the terminal screws loosened
sufficiently to allow a 1mm2 conductor to be
connected.

N/A

The plug and test equipment shall be
preconditioned at a temperature of 40±1ºC for 1
h, without the test force applied. Throughout the
test, all parts of the plug and test equipment
shall be maintained at this temperature.

For all plugs, the point of application of the force
of the plug along the pins, and the direction of
the force shall be-

a) in both directions along the line perpendicular
to the plane of the pin, and passing through the
centre of the pin; and
b) in that plane in both directions along a line at
right angles to that specified in Item(a).
Over a period of 10 s, the force shall be
gradually applied to each of the pins in the
manner prescribed in Items (a) and (b),
maintained at its maximum value for 10 s, and
then released. The deflection of the pins shall
be measured along the line of force relative to
the face of the rigid holding block during the
period when the force is applied. The maximum
deflection shall not exceed 2.0 mm.

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Page 68 of 73
AS/NZS 3112 (Partial)

Clause

J2.2.6.6

Requirement − Test

Result – Remark

Verdict

Following the test on all pins of a plug
conforming to Figure 2.1, any distortion 5 min
after the completion of the test on the last pin
shall be such that it will not prevent the plug
from being inserted in the appropriate standard
gauges shown in Appendix A, Appendix B and
Appendix F without the application of undue
force.

For other types of plugs, any distortion after 5
min shall be such as will not prevent the plug
being inserted into an appropriate socket-outlet
without the application of undue force.

N/A

Fixing of pins (2.13.9.2)

A separate sample of a plug shall be heated to
a temperature of 50±20ºC for 1 h and
maintained at that temperature during the whole
of tests, including the 5 min period after removal
of the test load.

The plug shall be held firmly in such a manner
that there will be no undue squeezing or
distortion of the body, and the means of holding
shall not assist in maintaining the pins in their
original position,

Each pin, in turn, shall have applied to it a force
which, over a period of 10 s, shall be increased
steadily to 60+0.6N and held at this value for 10
min.

Two tests on each pin shall be conducted, one
with the direction of force along the length of the
pin towards the body of the plug, and the other
with the direction of force along the length o f
the pin away from the body.

The attachment of pins shall be considered
inadequate if any pin is displaced relative to the
adjacent material of the body by more than 2.4
mm at any time during these tests, or if any pin
fails to return to within 0.8 mm of its nominal
length specified in Figure 2.1 within 5 min of the
removal of the test force,

Additional tests for plugs with insulated pins
(3112.2.13.13)

2.13.13 Additional tests on the insulation
material of insulated pin plugs

2.13.13.1 General

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Page 69 of 73
AS/NZS 3112 (Partial)

Clause

Requirement − Test

Result – Remark

Verdict

The material of the pin-insulation shall be
resistant to the stresses to which it may be
subjected at the high temperature likely to occur
in conditions approaching the bad connection
conditions and at low temperatures in particular
conditions of service.

Compliance shall be checked by the tests of
Clause 2.13.13.2 to 2.13.13.5

(a) Pressure test at high temperature
(2.13.13.2)

A specimen of one insulated pin only shall be
subjected to the following test by means of the
apparatus shown in Figure 2.2. This apparatus
shall have a blade having a round shape with a
diameter of 6 mm and a thickness of 0.7 mm.

The specimen shall be placed in position as
shown in the Figure 2.5 and a force of 2.5 N
shall be applied through the blade to specimen.

The apparatus, with the specimen in position,
shall be maintained for 2 h in a heating cabinet
at a temperature of 160+5ºC. The specimen
shall then be removed from the apparatus and
within 10 s, cooled by immersion in cold water.

The thickness of the insulation shall be
measured immediately at the point of
impression.

The thickness within the area of the impression
shall be not less than 50% of the thickness
measured before the test.

The impression no more than
50%

Visual inspection shall be made and no cracks
on the insulation material shall be visible with
normal, or corrected to normal, vision without
additional magnification, and the dimension of
the insulating material shall not have changed
below the minimum size shown in Figure 2.4.

(b) Static damp heat test (2.13.13.3)

An insulated pin plug shall be subjected to two
damp heat cycles in accordance with IEC
60068-2-30. Db (12+12 h cycle), 95% relative
humidity, lower temperature 25+3ºC and upper
temperature 40ºC.

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Page 70 of 73
AS/NZS 3112 (Partial)

Clause

Requirement − Test
After this treatment and after recovery to room
temperature, the specimen shall be subjected
to-

Result – Remark

Verdict
P

a) the insulation resistance test in
accordance with CLAUSE 2.13.2(E);
b) high voltage test in accordance with
Clause 2.13.3 and;
c) abrasion test in accordance with Clause
2.13.13.6.
NOTE: At the manufacturer’s option, the same
sample may be used for this test and the low
temperature test (see Clause 2.13.13.4) and a
single abrasion test may be done.
(c) Low temperature test (2.13.13.4)

An insulated pin plug shall be maintained at –
15+2ºC for at least 24 h and returned to room
temperature.

The specimen shall be subjected to –

a) the insulation resistance test in
accordance with Clause 2.13.2(e);
b) high voltage test in accordance with
Clause 2.13.3 and;
c) abrasion test in accordance with Clause
2.13.13.6.
NOTE: At the manufacturer’s option, the same
sample may be used for this test and the static
damp heat test (see Clause 2.13.13.3) and a
single abrasion test may be done.
(d) Impact test at low temperature (2.13.13.5)

A specimen of one insulated pin only shall be
subjected to an impact test by means of the
apparatus shown in Figure 2.6. The mass of the
falling weight shall be 100+1 g.

The apparatus, on a sponge rubber pad 40 mm
thick, together with the specimen, shall be
maintained at –15+20ºC for at least 24 h.

At the end of this period, the specimen shall be
placed in position, as shown in Figure 2.6, and
the falling weight shall be allowed to fall from a
height of 100mm. Four impacts shall be applied
successively to the same specimen, rotating it
through 90º between impacts.

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Page 71 of 73
AS/NZS 3112 (Partial)

Clause

Requirement − Test

Result – Remark

After the test the specimen shall be allowed to
return to room temperature and then examined,
No cracks of the insulating material shall be
visible with normal, or corrected to normal,
vision without additional magnification.

Verdict
P

NOTE: The cooling period of 14 h includes the
time necessary to cool down the apparatus.

J2.2.6.7

(e) Abrasion test (2.13.13.6)

An insulated pin of an insulated pin plug shall be
subjected to the following test by means of an
apparatus as shown in Figure 2.7.

The test apparatus comprises a horizontally
disposed beam, which shall be pivoted about its
centre point. A short length of steel wire, 1 mm
in diameter and bent into a U-shape, the base
of the U being straight, shall be rigidly attached,
at both ends, to one end of the beam, so that
the straight part projects below the beam and
shall be parallel to the axis of the beam pivot.

The plug shall be held in a suitable clamp in
such a position that the straight part of the steel
wire rests on the major axis face of the plug pin,
at right angles to it. The pin shall slope
downwards at an angle of 10º to the horizontal.

The beam shall be loaded so that the wire
exerts a force of 4 N on the pin.

The plug shall be moved backwards and
forwards in horizontal direction in the plane of
the axis of the beam, so that the wire rubs along
the pin. The length of the pin thus abraded shall
be approximately 9 mm, of which approximately
7 mm shall be over the insulation.

The number of movement s shall be 20 000 (10
000 in each direction) and the rate of operation
shall be 30 movements per min.

After the test, the pins shall show no damage
which may affect safety or impair the further use
of the plug, in particular, the insulating sleeve
shall not have punctured or rucked up.

Equipment with integral pins intended to be
supported by the contacts of a socket-outlet

Torque: 0.03 Nm

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Page 72 of 73
AS/NZS 3112 (Partial)

Clause

Result – Remark

Requirement − Test
G

Verdict

K
I

J
M
L

N
O

Symbol

Requirement

Measured (mm)

Symbol

(mm)

Requirement

Measured (mm)

(mm)

6.2 – 6.5

6.3

60 °

60°

1.58 – 1.78

1.60

> 8.6

10.5

7.92

7.96

R 19.0 – 21.0

20.7

16.66 – 17.46

17.20

< R 1.0

0.9

< 21.9 or > 27.0

20.7

8.2 – 9.2

8.3

< 21.9 or > 27.0

20.7

0.90 0.10

0.98

< 21.9 or > 27.0

20.7

6.0

< 21.9 or > 27.0

20.7

0.35 0.05

0.32

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Page 73 of 73
BS 4573 (Partial)

Clause

Result – Remark

Requirement − Test

Verdict

Plug dimensions (BS 4573: 1970)
Location

Requirement

Measured

Verdict

A: Diameter of plug pins

5.08±0.03

5.07

B: Length of projection of plug pins

15.87+1.0

15.9

C: Length of radiuses portion at the
end of plug pins

1.57+0.25

1.65

D: Nominal distance the centers of
plug pins

16.66±0.03

16.67

Note: Each of the above values is the average value of three samples.

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy

Picture 1

Picture 2

Page 1 of 11

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy

Picture 3

European plug pins were
fixed into enclosure by a
screw.

Picture 4

Page 2 of 11

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy

Picture 5

Picture 6

Page 3 of 11

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy

UK plug pins
were molded
into enclosure.

Picture 7

Picture 8

Page 4 of 11

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy

Australian plug
pins were molded
into enclosure.

Picture 9

Picture 10

Page 5 of 11

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy

Picture 11

Picture 12

Page 6 of 11

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy

Picture 13

The plug holder of
Indian plug is fixed
into enclosure by
screw.

Picture 14

Page 7 of 11

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy
Y capacitor
is optional

Picture 15
The cr and cl between
two pins of fusing
resistor is 2.7mm.

The cr and cl between
primary and secondary trace
on PCB is 6.7mm.
Picture 16

Page 8 of 11

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy

Picture 17

Picture 18

Page 9 of 11

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy

Picture 19

Picture 20

Page 10 of 11

Report Number:

16011089 001

Model:

DSA-5W-a Ab xy; DSA-5W-a Fb xy

Picture 21

Picture 22

Page 11 of 11

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16011089.001 503792 CB Certification

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