Untitled

Untitled
Page 2 of 82
Report No.:
11009010 001
Copy of marking plate:
Summary of testing:
● The maximum normal load condition of unit as below:
1) For unit consist power supply with DC/AC inverter board type PTB-1725:
- for plastic enclosure shape type C: Operation with full brightness, max. contrast of the LCD backlight
circuit, max. volume of speaker and dummy load of 2.5W for four USB ports (series A receptacle).
- for plastic enclosure shape type A: Operation with full brightness, max. contrast of the LCD backlight circuit
and max. volume of speaker.
2) For unit consist power supply with DC/AC inverter board type PTB-1806:
For plastic enclosure shape type B: Operation with full brightness, max. contrast of the LCD backlight circuit
and max. volume of speaker.
● The ambient was specified as 40°C by manufacture.
● This unit complied with stability test (sub-clause 4.1) for each enclosure shape (type A, B, C).
● The USB ports (for unit with plastic enclosure shape type C and consist with power supply with DC/AC
inverter board type PTB-1725), output (+20.5Vdc output) of power supply with DC/AC inverter board (type
PTB-1806) and main board output (type A: P308 output connector to key control board and P306 output
connector to speaker; type B: P307 output connector to key control baord and P310 output connector to
speaker) were complied with the limited power source (sub-clause 2.5).
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 3 of 82
Report No.:
11009010 001
Particulars: test item vs. test requirements
Equipment mobility .......................................: Movable equipment
Operating condition .......................................: Continuous
Mains supply tolerance (%) ...........................: +10% / -10%
Tested for IT power systems ........................: Yes (Norway)
IT testing, phase-phase voltage (V) .............: IT, 230V for Norway
Class of equipment .......................................: Class I
Mass of equipment (kg).................................: max. 5.9
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 ...........................: Nov., 2006
Date(s) of performance of test .....................: Nov., 2006
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):
AR, AT, AU, BE, CH, DE, DK, FI, FR, GB, GR, HU, IL, IN, IT, KR, MY, NL, NO, PL, SE, SG, SI
AR=Argentina, AT=Austria, AU=Australia, BE=Belgium, CA=Canada, CH=Switzerland, CN=China,
DE=Germany, DK=Denmark, FI=Finland, FR=France, GB=United Kingdom, GR=Greece, HU=Hungary,
IL=Israel, IN=India, IT=Italy, KE=Kenya, KR=Korea, MY=Malaysia, NL=The Netherlands, NO=Norway,
PL=Poland, SE=Sweden, SG=Singapore, SI=Slovenia, SK=Slovakia, US=United States of America.
For National Differences see end of this test report.
Factories:
1) Lite-On Computer Technology (Dong Guan) Co., Ltd.
N. San Heng Rd., Heng Jiao Ind. Zone, Xi Chen Zone, Shi Jie Town, Dongguan, Guangdong, P.R. China
2) Dongguan shijie yuanli electronics factory
Heng Jiao Ind. Zone, Shi Jie Town, Dong Guan City, Guang Dong Province, P.R. China
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 4 of 82
Report No.:
11009010 001
Definition of variables:
Variable:
Range of variable:
Content:
X
Can be 0-9, A-Z or blank
Marketing purpose, no technical differences.
General product information:
The equipment model AL2002W XXXX (X can be 0-9, A-Z or blank, trade mark: “acer”) is a 20” LCD Monitor
for the use in information technology equipment.
This equipment consists of following critical components:
- TFT LCD panel module
- Metal enclosure (inside the plastic enclosure, covering the switching power supply with DC/AC inverter
board and function control board)
- Building-in type switching power supply with DC/AC inverter board (refer to appended table 1.5.1 for
source details)
- Secondary function control board (as main board, SELV circuit; with one DVI and D-sub port)
- Plastic enclosure
- Key control board (as SELV circuits)
For unit construction deviation details, refer to below information
1). Plastic enclosure shape type A consist with following parts:
- Switching power supply with DC/AC inverter board type PTB-1725
- Metal enclosure shape type A
- Main board type A
2). Plastic enclosure shape type B consist with following parts:
- Switching power supply with DC/AC inverter board type PTB-1806
- Metal enclosure shape type B
- Main board type B
3). Plastic enclosure shape type C consist with following parts:
- Switching power supply with DC/AC inverter board type PTB-1725
- Metal enclosure shape type A
- Main board type B
- USB board
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 5 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Verdict
1
GENERAL
P
1.5
Components
P
1.5.1
General
See below.
P
Comply with IEC 60950 or relevant component
standard
(see appended table 1.5.1)
P
1.5.2
Evaluation and testing of components
Components, which are
certified to IEC and/or national
standards, are used correctly
within their ratings or had been
evaluated during this approval.
P
1.5.3
Thermal controls
No thermal controls provided.
N/A
1.5.4
Transformers
Transformer used is suitable for
the intended application and
complies with the relevant
requirements of the standard
and particularly with those of
Annex C.
P
1.5.5
Interconnecting cables
Interconnection cable provided
with the equipment is carrying
signals on energy level below
240VA.
P
Besides for the insulation
materials there are not other
requirements for the
interconnection cables.
1.5.6
Capacitors in primary circuits ...............................: Between lines: X2 sub-class
capacitor according to IEC
60384-14:1993 with 21 days
damp heat test.
P
Between Line/Neutral to earth:
Y2 or Y1 sub-class capacitor
according to IEC 6038414:1993.
1.5.7
Double insulation or reinforced insulation bridged
by components
No such components used.
N/A
1.5.7.1
General
See above.
N/A
1.5.7.2
Bridging capacitors
See above.
N/A
1.5.7.3
Bridging resistors
See above.
N/A
1.5.7.4
Accessible parts
See above.
N/A
1.5.8
Components in equipment for IT power systems
Y1 or Y2 subclass capacitors
according to IEC 60384-14:1993
provided between phase and
earth are rated 250Vac min.
TRF No.:IECEN60950_1B
P
TRF originator: SGS Fimko
Page 6 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Verdict
1.6
Power interface
1.6.1
AC power distribution systems
TN power system considered.
IT power system for Norway.
P
1.6.2
Input current
(see appended table 1.6.2)
P
1.6.3
Voltage limit of hand-held equipment
This appliance is not a handheld equipment.
1.6.4
Neutral conductor
The neutral is not identified in
the equipment. Basic insulation
for rated voltage between
earthed parts and primary
phases.
1.7
Marking and instructions
1.7.1
Power rating
P
N/A
P
P
See below.
P
Rated voltage(s) or voltage range(s) (V) .............: 100-240V~
P
Symbol for nature of supply, for d.c. only .............: AC mains only.
N/A
Rated frequency or rated frequency range (Hz) ..: 50/60Hz
P
Rated current (mA or A) ......................................: 1.5A
P
Manufacturer’s name or trademark or identification Acer
mark .....................................................................:
P
Type/model or type reference...............................: AL2002W XXXX (X can be 0-9,
A-Z or blank)
P
Symbol for Class II equipment only .....................: Class I equipment.
N/A
Other symbols ......................................................: Other symbols do not give rise
to misunderstanding.
P
Certification marks ...............................................: See copy of the marking plates
for the safety marks.
N/A
1.7.2
Safety instructions
User’s manual provided.
1.7.3
Short duty cycles
Equipment is designed for
continuous operation.
1.7.4
Supply voltage adjustment ...................................: Full range circuit design.
N/A
Methods and means of adjustment; reference to No such supply voltage
installation instructions .........................................: adjustment.
N/A
Power outlets on the equipment ..........................: No standard power outlets
provided.
N/A
1.7.5
TRF No.:IECEN60950_1B
P
N/A
TRF originator: SGS Fimko
Page 7 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
1.7.6
Fuse identification (marking, special fusing
Fuse marking label adjacent to
characteristics, cross-reference) ............................: the fuse holder on PCB:
Verdict
P
F801 T3.15AH 250V
CAUTION: FOR CONTINUED
PROTECTION AGAINST A RISK OF
FIRE REPLACE ONLY WITH SAME
TYPE AND RATINGS OF FUSE.
1.7.7
Wiring terminals
1.7.7.1
Protective earthing and bonding terminals ..........: Appliance inlet is provided. The
symbol 60417-1-IEC-5019 was
located on PCB.
1.7.7.2
Terminal for a.c. mains supply conductors
The equipment is provided with
appliance inlet, which is for
connection of a detachable type
power supply cord.
N/A
1.7.7.3
Terminals for d.c. mains supply conductors
No such conductors.
N/A
1.7.8
Controls and indicators
See below.
1.7.8.1
Identification, location and marking .....................: The marking and indication of
the stand-by switch is located
that indication of function is
clearly.
P
1.7.8.2
Colours ...............................................................: The colours of the Power LED
indicator are as follows:
- Green for ON condition
- Amber for stand-by condition
P
1.7.8.3
Symbols according to IEC 60417 .........................: Marking according 60417-1IEC- 5009 (line half inside
circle) for stand-by switch.
P
1.7.8.4
Markings using figures ........................................: No indicators for different
positions of control.
N/A
1.7.9
Isolation of multiple power sources .....................: Single power source only.
N/A
1.7.10
IT power distribution systems
For Norway compliance has to
be evaluated during the
national approved.
N/A
1.7.11
Thermostats and other regulating devices
Neither thermostats nor other
regulating devices provided.
N/A
1.7.12
Language(s) .........................................................: User’s manual provided in
English and German. Marking
label provided in English.
Versions in other languages will
be provided during national
approval.
TRF No.:IECEN60950_1B
P
See below.
P
P

TRF originator: SGS Fimko
Page 8 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
1.7.13
Durability
The marking plate was
subjected to the permanence
of marking test. The marking
plate was rubbed with cloth
soaked with water for 15 s and
then again for 15 s with the
cloth soaked with petroleum
spirit.
After this test there was no
damage to the marking. The
marking on the label did not
fade. There was no curling of
the marking.
P
1.7.14
Removable parts
No removable parts provided.
N/A
1.7.15
Replaceable batteries
No batteries provided.
N/A
Language(s)..........................................................:
Verdict

1.7.16
Operator access with a tool ..................................: There are no any operator
accessible areas with a tool
defined.
N/A
1.7.17
Equipment for restricted access locations ............: No restricted access locations.
N/A
2
PROTECTION FROM HAZARDS
P
2.1
Protection from electric shock and energy hazards
P
2.1.1
Protection in operator access areas
No hazards (electrical shock or
energy hazards) in operator
accessible areas.
P
2.1.1.1
Access to energized parts
See sub clause 2.1.1
P
Test by inspection ................................................: No access with test finger to
any parts with only basic
insulation to ELV or hazardous
voltage. Any hazardous parts
accessible are unlikely.
P
Test with test finger ..............................................: See above.
P
Test with test pin ..................................................: See above.
P
Test with test probe .............................................: No TNV circuit.
N/A
2.1.1.2
Battery compartments .........................................: No battery compartments
provided.
N/A
2.1.1.3
Access to ELV wiring
N/A
No ELV wiring in operator
access area.
Working voltage (Vpeak or Vrms); minimum
distance (mm) through insulation
2.1.1.4
Access to hazardous voltage circuit wiring
TRF No.:IECEN60950_1B

No hazardous voltage circuit in
operator access area.
N/A
TRF originator: SGS Fimko
Page 9 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
2.1.1.5
Energy hazards ....................................................: Energy does not exceed 240 VA
between any two points at
accessible parts.
2.1.1.6
Manual controls
No conductive shafts of
operating knobs and handles.
2.1.1.7
Discharge of capacitors in equipment
No risk of electric shock.
Time-constant (s); measured voltage (V) .............: (See appended table)
Verdict
P
N/A
P

2.1.2
Protection in service access areas
No maintenance works in
operation mode necessary.
N/A
2.1.3
Protection in restricted access locations
The unit is not limited to be used
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, 42.4Vpeak or
60Vd.c. are not exceeded.
Result see appended table
2.2.2.
P
2.2.3
Voltages under fault conditions (V).......................: Single fault did not cause
excessive voltage in SELV
circuits. The limits of 71Vpeak
and 120Vd.c. were not exceed.
Furthermore, the SELV limits
(see sub clause 2.2.2) were not
exceeded for longer than 0.2
seconds. Results see
appended tables 2.2.2 and
2.2.3.
P
2.2.3.1
Separation by double insulation or reinforced
insulation (method 1)
Method 1 used.
P
2.2.3.2
Separation by earthed screen (method 2)
Method 2 used.
P
2.2.3.3
Protection by earthing of the SELV circuit
(method 3)
2.2.4
Connection of SELV circuits to other circuits........: See sub clause 2.2.2, 2.2.3.
and 2.4.
2.3
TNV circuits
N/A
2.3.1
Limits
N/A
2.3.2
P
P
See below.
N/A
P
Type of TNV circuits .............................................:

Separation from other circuits and from accessible
parts
N/A
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 10 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Insulation employed..............................................:
2.3.3

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
Considered for output of
DC/AC inverter.
P
2.4.2
Limit values
See appended table 2.4.2.
P
Frequency (Hz) .....................................................: See appended table 2.4.2.

Measured current (mA).........................................: The peak drop voltage was
measured with an oscilloscope
at a 2kΩ non-inductive resistor.
Results see appended table
2.4.2.

Measured voltage (V) ...........................................: 1) 1.36kV (for power supply with
DC/AC inverter board type PTB1725)
2) 3.34kV (for power supply with
DC/AC inverter board type PTB1725)

Measured capacitance (µF) ..................................: 1) 22pF (for power supply with
DC/AC inverter board type PTB1725)
2) 10pF (for power supply with
DC/AC inverter board type PTB1725)

2.4.3
Connection of limited current circuits to other
circuits
P
2.5
Limited power sources
N/A
P
Complies.
P
For power supply with DC/AC inverter board type PTB-1806: +20.5Vdc output of
power supply with DC/AC inverter board and P310/P307 output connectors of main
board type B were complied with L.P.S test.
For main board types A, which consist with power supply with DC/AC inverter board
type PTB-1725, P308/P306 output connectors were complied with L.P.S test.
For USB ports, which consist with power supply with DC/AC inverter board type
PTB-1725, also were complied with L.P.S test.
Inherently limited output
N/A
Impedance limited output
N/A
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 11 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Overcurrent protective device limited output
Verdict
N/A
Regulating network limited output under normal
operating and single fault condition
For USB ports, +20.5Vdc
output of power supply with
DC/AC inverter board (type
PTB-1806), P308/P306 output
connector (main board type A)
and P310/P307 output
connector (main board type B)
were complied. See appended
table for test result.
Regulating network limited output under normal
operating conditions and overcurrent protective
device limited output under single fault condition
P
N/A
Output voltage (V), output current (A), apparent
Results see appended table
power (VA)............................................................: 2.5.

Current rating of overcurrent protective device (A)

2.6
Provisions for earthing and bonding
P
2.6.1
Protective earthing
Appliance inlet (with PE pin)
reliable connection to PCB and
also with screw to metal
enclosure.
P
One protective bonding
conductor (green/yellow wire)
connected to the approved
appliance inlet (hooked and
soldered) and to the PCB via
solder pin and soldered.
2.6.2
Functional earthing
Secondary functional earthing
is separated to primary by
double or reinforce insulation or
by basic insulation and
protective earthing. No
green/yellow wire used for
functional earthing.
P
2.6.3
Protective earthing and protective bonding
conductors
See below.
P
2.6.3.1
General
No power supply cord provided.
See sub clause 2.6.3.4.
P
2.6.3.2
Size of protective earthing conductors
No power cord provided.
2
Rated current (A), cross-sectional area (mm ),
AWG .....................................................................:
2.6.3.3
Size of protective bonding conductors
TRF No.:IECEN60950_1B
N/A

Evaluation by test. Rated
current below 16A.
N/A
TRF originator: SGS Fimko
Page 12 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Verdict
Rated current (A), cross-sectional area (mm2),
AWG .....................................................................:

2.6.3.4
Resistance (Ω) of earthing conductors and their
(Refer to appended table
terminations, test current (A) ................................: 2.6.3.4).
P
2.6.3.5
Colour of insulation ...............................................: The insulation of the protective
bonding conductor is
green/yellow wire.
P
2.6.4
Terminals
See below.
P
2.6.4.1
General
See sub clause 2.6.1.
P
2.6.4.2
Protective earthing and bonding terminals
The earth terminal of appliance
inlet is considered as the
protective earthing terminal and
was evaluated by sub clause
2.6.3.4.
P
Rated current (A), type and nominal thread
Evaluation by test. Rated
diameter (mm) ......................................................: current below 16A.

2.6.4.3
Separation of the protective earthing conductor
from protective bonding conductors
Only protective earthing
conductor used in this
equipment.
2.6.5
Integrity of protective earthing
See below.
P
2.6.5.1
Interconnection of equipment
This unit has it's own earthing
connection. Any other units
connected via the output shall
be provided SELV only.
P
2.6.5.2
Components in protective earthing conductors
and protective bonding conductors
No switch or overcurrent
protective device in protective
earthing or bonding conductor.
P
2.6.5.3
Disconnection of protective earth
Appliance inlet provided as
disconnection device.
P
2.6.5.4
Parts that can be removed by an operator
Plug or inlet, the earth
connection is made before and
broken after the hazardous
voltage. No other operator
removable parts provided.
P
2.6.5.5
Parts removed during servicing
It is not necessary to disconnect
the earth connection except for
the removing of the earthed part
itself.
P
2.6.5.6
Corrosion resistance
All safety earthing connections
in compliance with Annex J.
P
TRF No.:IECEN60950_1B
N/A
TRF originator: SGS Fimko
Page 13 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
2.6.5.7
Screws for protective bonding
Only ISO thread screw used in
metal chassis for protective
bonding. Metal thickness at
least twice the pitch of the
screw.
Verdict
N/A
No self-tapping or spaced
thread screws.
2.6.5.8
Reliance on telecommunication network or cable
distribution system
2.7
Overcurrent and earth fault protection in primary circuits
P
2.7.1
Basic requirements
Equipment relies on or circuit
breaker of the wall outlet
installation protection of the
building installation in regard to
L to N short circuit and earth
fault. Over current protection is
provided by one built-in fuse.
P
Instructions when protection relies on building
installation
Pluggable equipment type A.
2.7.2
Faults not covered in 5.3
The protection devices are well
dimensioned and mounted.
P
2.7.3
Short-circuit backup protection
Pluggable equipment type A, the
building installation is
considered as providing short
circuit backup protection.
P
2.7.4
Number and location of protective devices ..........: One built-in fuse provided on the
mains conductor.
P
2.7.5
Protection by several devices
2.7.6
Warning to service personnel ...............................: No service work necessary.
N/A
2.8
Safety interlocks
N/A
2.8.1
General principles
N/A
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
TRF No.:IECEN60950_1B
No TNV circuits provided.
One fuse provided.
N/A
N/A
N/A
TRF originator: SGS Fimko
Page 14 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Verdict
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
2.9.1
Properties of insulating materials
Natural rubber, asbestos or
hygroscopic materials are not
used.
P
2.9.2
Humidity conditioning
Carried out for 120 hrs.
P
P
Humidity (%) ........................................................: 95% R.H.

Temperature (°C) .................................................: 40°C

2.9.3
Grade of insulation
P
2.10
Clearances, creepage distances and distances through insulation
P
2.10.1
General
See below.
P
2.10.2
Determination of working voltage
The rms and the peak voltages
were measured for the unit.
P
Adequate levels of safety
insulation were provided and
maintained to comply with the
requirements of this standard.
The unit was connected to a
240V TN power system.
Results see appended table
2.10.2.
2.10.3
Clearances
See below, Annex G was not
considered.
P
2.10.3.1
General
Annex F and minimum
clearances considered.
P
2.10.3.2
Clearances in primary circuits
(see appended table 2.10.3
and 2.10.4)
P
2.10.3.3
Clearances in secondary circuits
Sub clause 5.3.4 considered.
N/A
2.10.3.4
Measurement of transient voltage levels
Normal transient voltage
considered (overvoltage
category II for primary circuits).
N/A
2.10.4
Creepage distances
(see appended table 2.10.3
and 2.10.4)
CTI tests ...............................................................: CTI rating for all materials of
min. 100, see appended table
C.2 for details.
TRF No.:IECEN60950_1B
P

TRF originator: SGS Fimko
Page 15 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
2.10.5
Solid insulation
See below.
P
2.10.5.1
Minimum distance through insulation
(see appended table 2.10.5)
P
2.10.5.2
Thin sheet material
The thin sheet materials of
polyester tape used in
transformer T801.
P
2.10.5.3
Number of layers (pcs) .........................................: 3 layers.

Electric strength test

(see appended table 5.2)
Printed boards
N/A
Distance through insulation
N/A
Electric strength test for thin sheet insulating
material
2.10.5.4
Verdict

Number of layers (pcs) .........................................:
N/A
Wound components
N/A
Number of layers (pcs) .........................................:
N/A
Two wires in contact inside wound component;
angle between 45° and 90° ..................................:
N/A
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
components.
N/A
Temperature T1=T2 + Tma – Tamb +10K (°C)....:
N/A
Spacings filled by insulating compound................: Certified photo-couplers used.
No other components applied
for.
P
Electric strength test

2.10.9
Component external terminations
See appended table 2.10.3 and
2.10.4.
2.10.10
Insulation with varying dimensions
No reduction of distances
considered.
3
WIRING, CONNECTIONS AND SUPPLY
TRF No.:IECEN60950_1B
P
N/A
P
TRF originator: SGS Fimko
Page 16 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
3.1
General
3.1.1
Current rating and overcurrent protection
All internal wires are UL
recognized wiring, which is
PVC insulated, rated VW-1,
min. 80°C, 300V. Internal
wiring gauge is suitable for
current intended to be carried.
P
3.1.2
Protection against mechanical damage
Wires do not touch sharp
edges and heatsinks, which
could damage the insulation.
P
3.1.3
Securing of internal wiring
Internal wires are secured by
solder, cable tie or other
mechenical connect so that a
loosening of the terminal
connection is unlikely.
P
3.1.4
Insulation of conductors
The insulation of the individual
conductors is suitable for the
application and the working
voltage. For the insulation
material see 3.1.1.
P
3.1.5
Beads and ceramic insulators
Not used.
N/A
3.1.6
Screws for electrical contact pressure
No electrical contact pressure
by screwed connection.
N/A
3.1.7
Insulating materials in electrical connections
All current carrying connections
made by metal to metal.
3.1.8
Self-tapping and spaced thread screws
No self-tapping or spaced
thread screws used.
3.1.9
Termination of conductors
All conductors are reliably
secured by solder-pin or glued
or other mechanical fixing
means.
P
10 N pull test
Complied.
P
3.1.10
Sleeving on wiring
No sleeving used as
supplementary insulation
function.
3.2
Connection to an a.c. mains supply or a d.c. mains supply
P
3.2.1
Means of connection ............................................: See below.
P
3.2.1.1
Connection to an a.c. mains supply
Appliance inlet used.
P
3.2.1.2
Connection to a d.c. mains supply
Only AC mains supply.
N/A
3.2.2
Multiple supply connections
Only one mains connection.
N/A
3.2.3
Permanently connected equipment
Not permanently connected
equipment.
N/A
TRF No.:IECEN60950_1B
Result – Remark
Verdict
P
P
N/A
N/A
TRF originator: SGS Fimko
Page 17 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Number of conductors, diameter (mm) of cable
and conduits ........................................................:
Verdict

3.2.4
Appliance inlets
The appliance inlet complies
with IEC 60320-1. The power
cord can be inserted without
difficulties and does not support
the unit.
3.2.5
Power supply cords
Not provided.
N/A
3.2.5.1
AC power supply cords
Not provided.
N/A
Type......................................................................:
P

2
Rated current (A), cross-sectional area (mm ),
AWG .....................................................................:

3.2.5.2
DC power supply cords
Not connect to DC mains.
N/A
3.2.6
Cord anchorages and strain relief
No non-detachable power
supply cords provided.
N/A
Mass of equipment (kg), pull (N) ........................:

Longitudinal displacement (mm) ..........................:

3.2.7
Protection against mechanical damage
No parts under this unit likely to
damage the power supply
cords. Enclosure without sharp
edges.
3.2.8
Cord guards
No cord guard provided.
P
N/A
D (mm); test mass (g) ..........................................:

Radius of curvature of cord (mm).........................:

3.2.9
Supply wiring space
Not permanently connected
and without non-detachable
power supply cord.
3.3
Wiring terminals for connection of external conductors
N/A
N/A
Neither permanently connected nor non-detachable equipment.
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
Rated current (A), cord/cable type, cross-sectional
area (mm2) ...........................................................:
3.3.5
Wiring terminal sizes
Rated current (A), type and nominal thread
diameter (mm) .....................................................:
TRF No.:IECEN60950_1B

N/A

TRF originator: SGS Fimko
Page 18 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
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
See below.
P
3.4.2
Disconnect devices
Appliance inlet used as
disconnect divice.
P
3.4.3
Permanently connected equipment
Not permanently connected
equipment.
3.4.4
Parts which remain energized
When the power cord is
removed from the inlet no
remaining parts with hazardous
voltage in the equipment.
3.4.5
Switches in flexible cords
No power supply cords
provided.
3.4.6
Single-phase equipment and d.c. equipment
Both poles are disconnected
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
Interconnection of the power
supply to the other PCBs in the
equipment by secondary output
cable only.
N/A
3.4.11
Multiple power sources
Only one supply connection
provided.
N/A
3.5
Interconnection of equipment
3.5.1
General requirements
3.5.2
Types of interconnection circuits ..........................: Interconnection circuits of
SELV through the connector.
3.5.3
ELV circuits as interconnection circuits
4
PHYSICAL REQUIREMENTS
P
4.1
Stability
P
TRF No.:IECEN60950_1B
Result – Remark
Verdict
P
N/A
P
N/A
P
P
P
See below.
No ELV interconnection.
P
N/A
TRF originator: SGS Fimko
Page 19 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Angle of 10°
The equipment does not
overbalance when tilted to 10
degrees (for all type of base
stand).
Test: force (N).......................................................: Equipment is not a floor
standing unit.
Verdict
P
N/A
4.2
Mechanical strength
4.2.1
General
See below. After the tests, the
equipment complies with the
requirements of sub-clauses
2.1.1, 2.6.1 and 2.10.
P
4.2.2
Steady force test, 10 N
10N applied to components
other than parts serving as an
enclosure.
P
4.2.3
Steady force test, 30 N
4.2.4
Steady force test, 250 N
250N applied to internal metal
enclosure at top, side, bottom
and rear. No energy or other
hazards.
P
4.2.5
Impact test
No hazard as result from steel
ball impact test for plastic
enclosure.
P
Fall test
See above.
P
Swing test
See above.
P
P
N/A
4.2.6
Drop test
4.2.7
Stress relief test
After the test at temperature of
70.4°C for plastic enclosure, no
shrinkage, distortion or
loosening of any enclosure part
was noticeable on the
equipment for all plastic
enclosure materials.
4.2.8
Cathode ray tubes
No CRT provided.
N/A
Picture tube separately certified ...........................:
N/A
N/A
4.2.9
High pressure lamps
4.2.10
Wall or ceiling mounted equipment; force (N) .....: Equipment is not a wall or
ceiling mounted equipment.
4.3
Design and construction
4.3.1
Edges and corners
TRF No.:IECEN60950_1B
P
No high pressure lamps
provided.
N/A
N/A
P
The edges and corners are
rounded and smoothed.
P
TRF originator: SGS Fimko
Page 20 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Verdict
4.3.2
Handles and manual controls; force (N) ...............: None, which could cause
hazards.
N/A
4.3.3
Adjustable controls
No safety relevant adjustable
controls provided.
N/A
4.3.4
Securing of parts
Electrical and mechanical
connections can be expected
to withstand usual mechanical
stress. No loosening of
clearance or creepage
impairing distances likely to
occur.
P
4.3.5
Connection of plugs and sockets
No mismatch of connectors,
plugs or socket possible.
P
4.3.6
Direct plug-in equipment
Not direct plug-in type.
N/A
Dimensions (mm) of mains plug for direct plug-in :
N/A
Torque and pull test of mains plug for direct
plug-in; torque (Nm); pull (N) ................................:
N/A
4.3.7
Heating elements in earthed equipment
No heating elements.
N/A
4.3.8
Batteries
No batteries provided.
N/A
4.3.9
Oil and grease
No oil or grease inside the
equipment.
N/A
4.3.10
Dust, powders, liquids and gases
Equipment 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 flammable liquid.
N/A
Quantity of liquid (l) ...............................................:
N/A
Flash point (°C).....................................................:
N/A
4.3.13
Radiation; type of radiation ..................................: See below.
P
4.3.13.1
General
P
4.3.13.2
Ionizing radiation
4.3.13.3
No radiation is generated inside
the equipment. The energy of
the indicator LED is far below
the limit for Class 1 LED
products.
N/A
Measured radiation (pA/kg) .................................:

Measured high-voltage (kV) ................................:

Measured focus voltage (kV) ...............................:

CRT markings .....................................................:

Effect of ultraviolet (UV) radiation on materials
TRF No.:IECEN60950_1B
N/A
TRF originator: SGS Fimko
Page 21 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Verdict
Part, property, retention after test, flammability
classification ........................................................:
N/A
4.3.13.4
Human exposure to ultraviolet (UV) radiation ......:
N/A
4.3.13.5
Laser (including LEDs)
No ionizing radiation or laser or
flammable liquids presents. LED
power is far below LED Class 1
limit.
Laser class ...........................................................: See above.
P

4.3.13.6
Other types ..........................................................: Not used.
N/A
4.4
Protection against hazardous moving parts
N/A
4.4.1
General
N/A
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
P
(see appended table 4.5.1)
P
Normal load condition per Annex L.......................: Considered.
P
4.5.2
Resistance to abnormal heat
P
4.6
Openings in enclosures
4.6.1
Top and side openings
4.6.2
Phenolic materials used in
where parts at hazardous
voltage are directly mounted
on. Phenolic is accepted
without further testing. Others
see appended table.
P
P
See below.
Dimensions (mm) ................................................: (see appended table)

Bottoms of fire enclosures
P
See below.
Construction of the bottom ...................................: (see appended table)

4.6.3
Doors or covers in fire enclosures
No doors or covers provided.
N/A
4.6.4
Openings in transportable equipment
Equipment not transportable
type.
N/A
4.6.5
Adhesives for constructional purposes
No adhesives used.
N/A
4.7
Conditioning temperature (°C)/time (weeks) ........:

Resistance to fire
P
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 22 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
4.7.1
Reducing the risk of ignition and spread of flame
See below.
P
Method 1, selection and application of
components wiring and materials
Materials with suitable
flammability classes are used.
P
Method 2, application of all of simulated fault
condition tests
Not used.
N/A
4.7.2
Conditions for a fire enclosure
See below.
P
4.7.2.1
Parts requiring a fire enclosure
Fire enclosure is required if at
least one of the following is
provided:
P
●
components in primary
●
components in secondary
(not supplied by LPS)
●
insulated wiring
Verdict
Fire enclosure is required.
4.7.2.2
Parts not requiring a fire enclosure
4.7.3
Materials
4.7.3.1
General
PCB rated accordingly. For
details see table 1.5.1.
P
4.7.3.2
Materials for fire enclosures
Internal metal enclosure was
considered as fire enclosure.
P
4.7.3.3
Materials for components and other parts outside
fire enclosures
The other part (base stand)
outside of fire enclosure used
material rated HB or better.
P
4.7.3.4
Materials for components and other parts inside
fire enclosures
Internal components except
small parts are V-2 or better.
P
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
5
ELECTRICAL REQUIREMENTS AND SIMULATED ABNORMAL CONDITIONS
P
5.1
Touch current and protective conductor current
P
5.1.1
General
See sub-clauses 5.1.2 to 5.1.6.
P
5.1.2
Equipment under test (EUT)
EUT has only one mains
connection.
P
5.1.3
Test circuit
Equipment of figure 5A used.
P
5.1.4
Application of measuring instrument
See appended table 5.1.6.
P
TRF No.:IECEN60950_1B
Key control board and speaker
were supplied by limited power
source and components were
mounted on V-1 PCB which
outside the metal enclosure.
P
P
TRF originator: SGS Fimko
Page 23 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Verdict
5.1.5
Test procedure
The touch current was
measured from mains to metal
enclosure, output connector and
plastic enclosures with metal
foil.
P
5.1.6
Test measurements
See appended table 5.1.6.
P
Test voltage (V) ...................................................: See above.

Measured touch current (mA) ..............................: See above.

Max. allowed touch current (mA) .........................: See above.

Measured protective conductor current (mA) ......:

Max. allowed protective conductor current (mA) .:

5.1.7
Equipment with touch current exceeding 3.5 mA : Touch current does not exceed
3.5mA.
N/A
5.1.8
Touch currents to and from telecommunication
No TNV circuit connection.
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
No TNV circuit connection.
telecommunication networks ................................:
5.2
Electric strength
5.2.1
General
(see appended table 5.2)
P
5.2.2
Test procedure
(see appended table 5.2)
P
5.3
Abnormal operating and fault conditions
5.3.1
Protection against overload and abnormal
operation
See below.
5.3.2
Motors
No motors used.
5.3.3
Transformers
With the overload and shorted
output of the transformer, no
high temperature of the
transformer was recorded.
N/A
P
P
P
N/A
P
Results of the overload and
short-circuit tests see appended
table 5.3 and Annex C.
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 24 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
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
Ventilation blocked: Results
see appended table.
Verdict
P
N/A
P
Short and open circuit test for
power supply board. Result 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 occurs. No molten metal
was emitted. Electric strength
tests primary to secondary and
primary to earth were passed.
P
6
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
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
7
Max. output current (A) .........................................:

Current limiting method ........................................:

CONNECTION TO CABLE DISTRIBUTION SYSTEMS
TRF No.:IECEN60950_1B
N/A
TRF originator: SGS Fimko
Page 25 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
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
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) .............................................:

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
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 26 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
A.2.7
Requirement – Test
Result – Remark
Verdict
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
B
ANNEX B, MOTOR TESTS UNDER ABNORMAL CONDITIONS (see 4.7.2.2 and
5.3.2)
N/A
B.1
General requirements
N/A
Position ................................................................:

Manufacturer ........................................................:

Type .....................................................................:

Rated values .......................................................:

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) ...........................................:
TRF No.:IECEN60950_1B

TRF originator: SGS Fimko
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C
ANNEX C, TRANSFORMERS (see 1.5.4 and 5.3.3)
P
Position ................................................................: T801

Manufacturer ........................................................: (see appended table C.2)

Type .....................................................................: (see appended table C.2)

Rated values .......................................................: Class B

Method of protection .............................................: By the circuit design.

C.1
Overload test
(see appended table 5.3)
P
C.2
Insulation
(see appended table C.2)
P
Protection from displacement of windings ............: By additional insulation tape.
P
D
ANNEX D, MEASURING INSTRUMENTS FOR TOUCH-CURRENT TESTS
(see 5.1.4)
P
D.1
Measuring instrument
P
D.2
Alternative measuring instrument
N/A
E
ANNEX E, TEMPERATURE RISE OF A WINDING (see 1.4.13)
N/A
F
ANNEX F, MEASUREMENT OF CLEARANCES AND CREEPAGE DISTANCES
(see 2.10)
G
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
H
ANNEX H, IONIZING RADIATION (see 4.3.13)
N/A
TRF No.:IECEN60950_1B
See sub clause 5.1.3 and 5.1.4
P
TRF originator: SGS Fimko
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J
ANNEX J, TABLE OF ELECTROCHEMICAL POTENTIALS (see 2.6.5.6)
P
Metal used ...........................................................: Complied.

K
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
L
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
M
ANNEX M, CRITERIA FOR TELEPHONE RINGING SIGNALS (see 2.3.1)
N/A
M.1
Introduction
N/A
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
TRF No.:IECEN60950_1B
See sub clause 1.6.2.
P
P
TRF originator: SGS Fimko
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M.3.2.3
Monitoring voltage (V)...........................................:
N/A
N
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
P
ANNEX P, NORMATIVE REFERENCES
P
Q
ANNEX Q, BIBLIOGRAPHY
P
R
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
S
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
T
ANNEX T, GUIDANCE ON PROTECTION AGAINST INGRESS OF WATER
(see 1.1.2)
N/A

U
ANNEX U, INSULATED WINDING WIRES FOR USE WITHOUT INTERLEAVED
INSULATION (see 2.10.5.4)
N/A

V
ANNEX V, AC POWER DISTRIBUTION SYSTEMS (see 1.6.1)
P
V.1
Introduction
See below.
P
V.2
TN power distribution systems
Single-phase TN power system
considered and used for
testing.
P
V.3
TT power systems
Not considered.
V.4
IT power systems
IT power system for Norway.
TRF No.:IECEN60950_1B
N/A
P
TRF originator: SGS Fimko
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Clause
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W
ANNEX W, SUMMATION OF TOUCH CURRENTS
N/A
W.1
Touch current from electronic circuits
N/A
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
X
ANNEX X, MAXIMUM HEATING EFFECT IN TRANSFORMER TESTS
(see clause C.1)
N/A
X.1
Determination of maximum input current
N/A
X.2
Overload test procedure
N/A
Y
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
Result – Remark
Verdict
TRF originator: SGS Fimko
Page 31 of 82
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Verdict
CENELEC COMMON MODIFICATIONS [C],
SPECIAL NATIONAL CONDITIONS [S] AND A-DEVIATIONS (NATIONAL DEVIATIONS) [A]
(EN 60950-1:2001, Annex ZB and Annex ZC)
P
General
P
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
Deleted.
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.
No power supply cord provided.
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 such switches used.
N/A
thermostats, relays and level controllers are not allowed.
1.5.8
1.7.2
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).
Considered.
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.
Should be evaluated during
national approval.
TYPE A
P
N/A
The marking text in the applicable countries shall
be as follows:
FI: "Laite on liitettävä suojamaadoituskoskettimilla See above.
varustettuun pistorasiaan"
N/A
NO: "Apparatet må tilkoples jordet stikkontakt"
See above.
N/A
SE: "Apparaten skall anslutas till jordat uttag"
See above.
N/A
A (DK, Heavy Current Regulations): Supply cords See above.
of class I equipment, which is delivered without a
plug, must be provided with a visible tag with the
following text:
N/A
Vigtigt!
Lederen med grøn/gul isolation må kun tilsluttes
en klemme mærket
TRF No.:IECEN60950_1B
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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:
"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.
1.7.5
A (DK, Heavy Current Regulations):
Class I equipment.
shall not be fitted with socketoutlets for providing power to other equipment.
No socket-outlets provided.
N/A
N/A
CLASS II EQUIPMENT
1.7.12
A (DE, Gesetz über technische Arbeitsmittel
German user’s manual
(Gerätesicherheitsgesetz) [Law on technical
provided.
labour equipment {Equipment safety law}], of 23rd
October 1992, Article 3, 3rd paragraph, 2nd
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
Equipment safety law], of 10th January 1996,
article 2, 4th 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.
P
NOTE: Of this requirement, rules for use even only by service
personnel are not exempted.
1.7.15
A (CH, Ordinance on environmentally hazardous
substances SR 814.013):
Annex 4.10 of SR 814.013 applies for batteries.
No battries provided.
A (DE, Regulation on protection against hazards This national difference was
by X-ray, of 8th January 1987, Article 5 [Operation deleted by A11 of EN 60950-1.
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 µSv/h and
TRF No.:IECEN60950_1B
N/A
N/A
TRF originator: SGS Fimko
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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
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.
No TNV circuits.
N/A
2.3.2
S (NO): Requirements according to this annex,
6.1.2.1 apply.
No TNV circuits.
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.
No TNV circuits.
N/A
2.6.3.3
S (GB): The current rating of the circuit shall be
taken as 13 A, not 16 A.
Considered.
N/A
2.7.1
C: Replace the subclause as follows:
Replaced.
P
Basic requirements
To protect against excessive current, shortcircuits and earth faults in PRIMARY CIRCUITS,
protective devices shall be included either as
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Verdict
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
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
Equipment is not direct plug-in
and short-circuits in the PRIMARY CIRCUIT OF
equipment.
DIRECT PLUG-IN EQUIPMENT, protective device shall
be included as integral parts of the DIRECT PLUGIN EQUIPMENT.
N/A
2.7.2
C: Void.
Declared.
N/A
2.10.2
C: Replace in the first line "(see also 1.4.7)" by
"(see also 1.4.8)".
Replaced.
P
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.
P
TRF No.:IECEN60950_1B
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Verdict
3.2.1.1
S (CH): Supply cords of equipment having a
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:
No power supply cord provided.
N/A
No power supply cord provided.
N/A
No power supply cord provided.
N/A
RATED CURRENT
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
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.
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.
TRF No.:IECEN60950_1B
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Clause
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Verdict
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.
No power supply cord provided.
N/A
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.
No power supply cord provided.
N/A
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
NOTE – 'Standard plug' is defined in SI 1768:1994 and
essentially means an approved plug conforming to BS 1363
or an approved conversion plug.
"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)
0,751)
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
1,25 mm2 is allowed for equipment with a rated
current over 10 A and up to and including 13 A.
No power supply cord provided.
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.
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 37 of 82
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Clause
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Result – Remark
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.
No power supply cord provided.
N/A
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.
EUT is not direct plug-in type.
N/A
4.3.13.6
Verdict
S (IE): DIRECT PLUG-IN EQUIPMENT is known as
See above.
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.
N/A
C: Add the following note:
Added.
N/A
No TNV circuits provided.
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:
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
TRF No.:IECEN60950_1B
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Verdict
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 circuits provided.
N/A
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.
7.1
S (FI, NO, SE): Requirements according to this
No TNV circuit or cable
annex, 6.1.2.1 and 6.1.2.2 apply with the term
distribution system provided.
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.
Considered.
N/A
Annex H
C: Replace the last paragraph of this annex by:
Replaced.
N/A
Replaced.
P
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.
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 39 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test
Result – Remark
Annex Q
C: Replace the title of IEC 61032 by "Protection of persons and equipment by
enclosures – Probes for verification".
Verdict
P
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.
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 40 of 82
Report No.:
11009010 001
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
HD 21 1) Series
HD 22 2) Series
EN 60309 Series
EN 60317-43:1997
EN 60320 Series
HD 384.3 S2:1995
HD 384.4.41 S2:1996
EN 132400:1994 4)
+ 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
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
IEC 60364-4-41 (mod):1992 3)
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
TRF originator: SGS Fimko
Page 41 of 82
Report No.:
11009010 001
IEC 60950-1 / EN 60950-1
Clause
Requirement – Test


EN ISO 527 Series

EN ISO 4892 Series

EN ISO 8256:1996

EN ISO 9773:1998


Result – Remark
Verdict
ISO 261:1998
ISO 262:1998
ISO 527 Series
ISO 386:1984
ISO 4892 Series
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
TRF originator: SGS Fimko
Page 42 of 82
1.5.1
Report No.:
11009010 001
TABLE: list of critical components
Object/part no.
Manufacturer/
trademark
P
Type/model
Technical data
Standard
PTB-1725
I/P: 100-240Vac, -50/60Hz, 1.30.9A;
O/P: 5.1Vdc /
3.48A,
20.68Vdc/
1.74A,
12.08Vdc/ 1.03A
(for power
supply)
Mark(s) of
conformity 1.
LCD Monitor unit
Switching Power Lite-on
Supply with
DC/AC inverter
board
Tested in
apparatus
I/p: 20.68Vdc,
1.74A;
o/p: 2400Vrms,
8.0mA (for
DC/AC inverter)
Switching Power Lite-on
Supply with
DC/AC inverter
board
PTB-1806
I/P: 100-240Vac, -50/60Hz, 1.5A;
O/P: 5.32Vdc /
1.9A, 22.64Vdc/
1.32A (for power
supply)
Tested in
apparatus
I/p: 22.64Vdc,
1.32A;
o/p: 2400Vrms,
7.0mA (for
DC/AC inverter)
LCD Panel
ChungHwa
CLAA201WA03
20.1”, TFT type,
1680X1050
--
--
AUO
M201EW02
20.1”, TFT type,
1680X1050
--
--
Base stand
--
--
Plastic material
HB min. cover
with metal
UL 94
UL
Metal enclosure
--
--
Metal, Thickness -min 0.81 mm
--
Plastic
Enclosure
LG Chemical
HF-380
HB, thickness
1.8mm min
UL 94
UL
Mylar sheet
between Power
supply board
component side
and metal
enclosure
--
--
V-2 or better,
cover area
170mm by
210mm
UL 94
UL
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 43 of 82
Report No.:
11009010 001
Speakers
(Two provided)
(Optional)
--
--
Each 4Ω, 2W
max.
--
--
P.C.B.
--
--
V-1, 105°C min
UL 94
UL
Power supply with DC/AC inverter board: PTB-1725
Appliance Inlet
(P801)
Fuse (F801)
X Capacitor
(C803, C806)
(optional)
Y-Capacitor
(C802, C808,
C805, C836,
C838, C839)
(Y1 or Y2 type)
(optional)
Solteam
ST-01
10A, 250Vac
IEC 60320-1
VDE, S, D, N, FI,
UL, CSA, SEV
Inalways
0707-1, 0711-2
10A, 250Vac
IEC 60320-1
VDE, S, D, N, FI,
UL, CSA, SEV
Duoling
CDJ-3
10A, 250Vac
IEC 60320-1
VDE, S, D, N, FI,
UL, CSA, SEV
Littelfuse
215
T3.15AH,
250Vac
IEC 60127-1
IEC 60127-2
VDE, S, UL
Bel
5HT
T3.15AH,
250Vac
IEC 60127-1
IEC 60127-2
VDE, S, UL
Hua Jung
MKP
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, SEV, UL,
CSA, FI
Matsushita
ECQ-UV,
ECQUL
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, SEV, S, N,
D, FI, UL, CSA
Pilkor
PCX2 337
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, SEV, S, N,
D, FI, UL
Teapo
XG-VS
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, SEV, S, N,
D, FI, UL,
CSA
Iskra
KNB1560
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, UL, CUL
Europtronic
MPX
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, UL, CUL
Matsushita
TS, RS, NS-A
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, UL,
CSA, FI
Pan Overseas
AC, AH
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
Success
SF, SE
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
Success
SB
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
TDK
CD
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 44 of 82
Murata
KX, KD
Dongguan South F
Hongming
Report No.:
11009010 001
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
Ripple Capacitor -(C801)
Electrolytic can
type
100-150µF,
400Vmin.,
105°C
--
--
Bleeder Resistor -(R802)
Carbon type
1MΩ, 1/4 W
--
--
Thermistor
(R801)
--
NTC type
10 Ω, 5A at 25°C --
--
Bridge Diode
(D813, D814,
D815, D816)
--
--
600V, 2A
--
--
Current sense
resistor (R813)
--
--
0.24Ω, 2W
--
--
Switching
Transistor
(Q801)
--
--
600V, 7.5A
--
--
Power
Transformer
(T801)
L.S.E
613106142X (X: Class B
0-9 for
marketing
purpose)
Applicable parts Tested with this
appliance
in IEC 60950-1
and according to
IEC 60085
Line Filter
(T802)
LSE
613800440X (X: 130°C
0-9 for
marketing
purpose)
--
--
LSE
613800000X (X: 130°C
0-9 for
marketing
purpose)
--
--
LSE
613800440X (X: 130°C
0-9 for
marketing
purpose)
--
--
LSE
613800000X (X: 130°C
0-9 for
marketing
purpose)
--
--
LSE
613102220X (X: 130°C
0-9 for
marketing
purpose)
--
--
Line Filter
(T803)
DC/AC Inverter
Transformer
(T101, T102)
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 45 of 82
Optocoupler
(I802)
Report No.:
11009010 001
LITEON
LTV-817
Di = 0.4 mm,
In = 4.0 mm,
Ex = 8.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
LITEON
LTV-816
Di = 0.6 mm,
In = 4.6 mm,
Ex = 7.4 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
LITEON
LTV-713 series
Di = 0.4 mm,
In = 2.0 mm,
Ex = 8.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
NEC
PS 2561
Di = 0.4 mm,
In = 4.0 mm,
Ex = 7.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
NEC
PS2581
Di = 0.4 mm,
In = 4.0 mm,
Ex = 8.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
NEC
PS2561A-1
series
Di = 0.4 mm,
In = 4.0 mm,
Ex = 7.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
QT
H11A817A
H11A817B
H11A817C
Di=0.4 mm,
exter creepage
= 7.0 mm,
thermal cycling,
AC 3000V.
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Sharp
PC123
Di = 0.7 mm,
In = 5.0 mm,
Ex = 8.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Sharp
PC817
Di = 0.4 mm,
In = 5 mm,
Ex = 6.4 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Toshiba
TLP621
DIN EN 60747Di=0.8 mm,
exter creepage 5-2: 2003,
IEC 60950-1
= 8.0 mm,
Thermal cycling,
AC 3000V.
VDE, FI
Toshiba
TLP721
Di = 0.8 mm,
In = 4.0 mm,
Ex = 8.0 mm,
Min.100°C
VDE, FI
TRF No.:IECEN60950_1B
DIN EN 607475-2: 2003,
IEC 60950-1
TRF originator: SGS Fimko
Page 46 of 82
Report No.:
11009010 001
Toshiba
TLP421 series
DIN EN 60747Di=0.4 mm,
exter creepage 5-2: 2003,
IEC 60950-1
= 8.0 mm,
Thermal cycling,
AC 3000V.
VDE, FI
Vishay
TCET1100
TCET1102
TCET1103
TCET1107
TCET1108
TCET1109
Di = 0.6 mm,
In = 4.2 mm,
Ex = 8.1 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Vishay
TCET1103G
TCET1107G
TCET1108G
TCET1109G
Di = 0.7 mm,
In = 4.2 mm,
Ex = 8.1 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Power supply with DC/AC inverter board: PTB-1806
Appliance Inlet
(P801)
Fuse (F801)
X Capacitor
(C801, C819)
(optional)
Y-Capacitor
(C808, C820,
C825)
(Y1 or Y2 type)
(optional)
Solteam
ST-01
10A, 250Vac
IEC 60320-1
VDE, S, D, N, FI,
UL, CSA, SEV
Inalways
0707-1, 0711-2
10A, 250Vac
IEC 60320-1
VDE, S, D, N, FI,
UL, CSA, SEV
Duoling
CDJ-3
10A, 250Vac
IEC 60320-1
VDE, S, D, N, FI,
UL, CSA, SEV
Littelfuse
215
T3.15AH,
250Vac
IEC 60127-1
IEC 60127-2
VDE, S, UL
Bel
5HT
T3.15AH,
250Vac
IEC 60127-1
IEC 60127-2
VDE, S, UL
Hua Jung
MKP
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, SEV, FI,
UL, CSA
Matsushita
ECQ-UV,
ECQUL
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, SEV, S, N,
D, FI, UL, CSA
Pilkor
PCX2 337
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, SEV, S, N,
D, FI, UL
Teapo
XG-VS
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, SEV, S, N,
D, FI, UL, CSA
Iskra
KNB1560
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, UL, cUL
Europtronic
MPX
Max. 0.47 µF,
250Vac
IEC 60384-14/
1993
VDE, UL, cUL
Matsushita
TS, RS, NS-A
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, UL,
CSA, FI
Pan Overseas
AC, AH
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 47 of 82
Report No.:
11009010 001
Success
SF, SE
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
Success
SB
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
TDK
CD
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
Murata
KX, KD
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
470-4700pF,
250Vac
IEC 60384-14/
1993
VDE, FI, UL,
CSA
Dongguan South F
Hongming
Ripple Capacitor -(C805)
Electrolytic can
type
100-150µF,
400Vmin.,
105°C
--
--
Bleeder Resistor -(R801)
Carbon type
1MΩ, 1/4 W
--
--
Thermistor
(R802)
--
NTC type
10 Ω, 3A at 25°C --
--
Bridge Diode
(D807, D808,
D805, D812)
--
--
600V, 2A
--
--
Current sense
resistor (R811)
--
--
0.39Ω, 2W
--
--
Switching
Transistor
(Q803)
--
--
600V, 7A
--
--
Power
Transformer
(T801)
L.S.E
6131053702P
Class B
Applicable parts Tested with this
appliance
in IEC 60950-1
and according to
IEC 60085
LI TAI
6131053702P60 Class B
Applicable parts Tested with this
appliance
in IEC 60950-1
and according to
IEC 60085
DGBullWill
6138003611P
130°C
--
--
LSE
6138003601P
130°C
--
--
DC/AC Inverter
Transformer
(T101, T102)
Darfon
6131020002P00 130°C
--
--
Optocoupler
(I802)
LITEON
LTV-817
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Line Filter
(T802)
TRF No.:IECEN60950_1B
Di = 0.4 mm,
In = 4.0 mm,
Ex = 8.0 mm,
Min.100°C
TRF originator: SGS Fimko
Page 48 of 82
Report No.:
11009010 001
LITEON
LTV-816
Di = 0.6 mm,
In = 4.6 mm,
Ex = 7.4 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
LITEON
LTV-713 series
Di = 0.4 mm,
In = 2.0 mm,
Ex = 8.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
NEC
PS 2561
Di = 0.4 mm,
In = 4.0 mm,
Ex = 7.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
NEC
PS2581
Di = 0.4 mm,
In = 4.0 mm,
Ex = 8.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
NEC
PS2561A-1
series
Di = 0.4 mm,
In = 4.0 mm,
Ex = 7.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
QT
H11A817A
H11A817B
H11A817C
Di=0.4 mm,
exter creepage
= 7.0 mm,
thermal cycling,
AC 3000V.
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Sharp
PC123
Di = 0.7 mm,
In = 5.0 mm,
Ex = 8.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Sharp
PC817
Di = 0.4 mm,
In = 5 mm,
Ex = 6.4 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Toshiba
TLP621
DIN EN 60747Di=0.8 mm,
exter creepage 5-2: 2003,
IEC 60950-1
= 8.0 mm,
Thermal cycling,
AC 3000V.
VDE, FI
Toshiba
TLP721
Di = 0.8 mm,
In = 4.0 mm,
Ex = 8.0 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Toshiba
TLP421 series
DIN EN 60747Di=0.4 mm,
exter creepage 5-2: 2003,
IEC 60950-1
= 8.0 mm,
Thermal cycling,
AC 3000V.
VDE, FI
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 49 of 82
Report No.:
11009010 001
Vishay
TCET1100
TCET1102
TCET1103
TCET1107
TCET1108
TCET1109
Di = 0.6 mm,
In = 4.2 mm,
Ex = 8.1 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Vishay
TCET1103G
TCET1107G
TCET1108G
TCET1109G
Di = 0.7 mm,
In = 4.2 mm,
Ex = 8.1 mm,
Min.100°C
DIN EN 607475-2: 2003,
IEC 60950-1
VDE, FI
Note(s):
1. An asterisk indicates a mark that assures the agreed level of surveillance.
2. In Optocoupler technical data column, where “Di” means distance through insulation, “In” means internal
creepage distance, “Ex” means external creepage distance.
1.6.2
Fuse #
TABLE: electrical data (in normal conditions)
Irated (A)
U(V)/F(Hz)
P (W)
P
I (A)
Ifuse (A)
Condition/status
Power supply with DC/AC inverter board: PTB-1725
F801
--
90/50
59.0
1.1
1.1
Maximum normal load conditions
F801
--
90/60
59.0
1.1
1.1
Maximum normal load conditions
F801
1.5
100/50
57.5
1.0
1.0
Maximum normal load conditions
F801
1.5
100/60
57.5
1.0
1.0
Maximum normal load conditions
F801
1.5
240/50
55.6
0.54
0.54
Maximum normal load conditions
F801
1.5
240/60
55.6
0.54
0.54
Maximum normal load conditions
F801
--
254/50
55.6
0.51
0.51
Maximum normal load conditions
F801
--
254/60
55.6
0.51
0.51
Maximum normal load conditions
F801
--
264/50
55.2
0.49
0.49
Maximum normal load conditions
F801
--
264/60
55.2
0.49
0.49
Maximum normal load conditions
Power supply with DC/AC inverter board: PTB-1806
F801
--
90/50
47.0
0.89
0.89
Maximum normal load conditions
F801
--
90/60
47.0
0.90
0.90
Maximum normal load conditions
F801
1.5
100/50
47.0
0.81
0.81
Maximum normal load conditions
F801
1.5
100/60
47.0
0.83
0.83
Maximum normal load conditions
F801
1.5
240/50
46.0
0.42
0.42
Maximum normal load conditions
F801
1.5
240/60
46.0
0.42
0.42
Maximum normal load conditions
F801
--
254/50
46.0
0.40
0.40
Maximum normal load conditions
F801
--
254/60
46.0
0.40
0.40
Maximum normal load conditions
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 50 of 82
Report No.:
11009010 001
F801
--
264/50
46.0
0.39
0.39
Maximum normal load conditions
F801
--
264/60
46.0
0.39
0.39
Maximum normal load conditions
Power supply with DC/AC inverter board: PTB-1725 with USB ports
F801
--
90/50
67.5
1.23
1.23
Maximum normal load conditions
F801
--
90/60
67.3
1.24
1.24
Maximum normal load conditions
F801
1.5
100/50
66.5
1.12
1.12
Maximum normal load conditions
F801
1.5
100/60
66.4
1.13
1.13
Maximum normal load conditions
F801
1.5
240/50
64.0
0.57
0.57
Maximum normal load conditions
F801
1.5
240/60
64.0
0.56
0.56
Maximum normal load conditions
F801
--
254/50
64.0
0.54
0.54
Maximum normal load conditions
F801
--
254/60
64.0
0.54
0.54
Maximum normal load conditions
F801
--
264/50
64.0
0.53
0.53
Maximum normal load conditions
F801
--
264/60
64.0
0.53
0.53
Maximum normal load conditions
Note(s):
2.1.1.5
TABLE: max. V, A, VA test
Voltage (rated)
(V)
N/A
Current (rated)
(A)
Voltage (max.)
(V)
Current (max.)
(A)
VA (max.)
(VA)
Note(s):
2.1.1.7
TABLE: discharge test
Condition
P
τ calculated τ measured
(s)
(s)
t u→ 0V
(s)
Comments
Power supply with DC/AC inverter board: PTB-1725
Line to Neutral
0.94
0.18
--
Vpk=354V, 37% of Vpk=131V, after 1 sec
voltage drop to 0V
--
Vpk=368V, 37% of Vpk=136V, after 1 sec
voltage drop to 104V
Power supply with DC/AC inverter board: PTB-1806
Line to Neutral
TRF No.:IECEN60950_1B
0.94
0.77
TRF originator: SGS Fimko
Page 51 of 82
Report No.:
11009010 001
Note(s):
For Power supply with DC/AC inverter board: PTB-1725:
Overall capacity:
0.94µF (C803=C806=0.47µF)
Discharge resistor:
1MΩ (R802=1MΩ)
For Power supply with DC/AC inverter board: PTB-1806:
Overall capacity:
0.94µF(C801=C819=0.47µF)
Discharge resistor:
1MΩ (R801=1MΩ)
2.2.2
TABLE: Hazardous voltage measurement
Transformer
P
Location
max. Voltage
V peak
V d.c.
Voltage Limitation
Component
Power supply with DC/AC inverter board: PTB-1725
T801
Pin 9, 10 – Pin 8
26.0
9.0
--
T801
Pin 13 – Pin 8
101
32.6
--
After D805
22.8
13.7
D805
Pin 11 – Pin 8
66
20.9
--
After D807
16.8
9.9
D807
T801
Power supply with DC/AC inverter board: PTB-1806
T801
Pin 7, 8 – Pin 6
31.4
--
--
T801
Pin 10 – Pin 6
121.0
--
--
After D809
--
26.4
D809
Note(s): Input Voltage is 240Vac, 60Hz
2.2.3
TABLE: SEL voltage measurement
Location
Voltage measured (V)
P
Comments
Power supply with DC/AC inverter board: PTB-1725
+12V output
0
When D807 short, the o/p-voltage did not
exceed 42.4Vpk.
+5V output
0
When D805 short, the o/p-voltage did not
exceed 42.4Vpk.
Power supply with DC/AC inverter board: PTB-1806
+20.5V output
0
When D809 short, the o/p-voltage did not
exceed 42.4Vpk.
Note(s): Input Voltage is 240Vac, 60Hz
2.4.2
TABLE: limited current circuit measurement
TRF No.:IECEN60950_1B
P
TRF originator: SGS Fimko
Page 52 of 82
Location
Voltage
(V)
Current
(mA)
Freq.
(kHz)
Report No.:
Limit
(mA)
11009010 001
Comments
Power supply with DC/AC inverter board: PTB-1725
With normal condition
P103 pin 1 – P103 pin 2
44
22
47
32.9
--
P103 pin 1 – Earth
0
0
--
--
P103 pin 2 – Earth
21.2
10.6
46
32.2
T101 pin 9 – Earth
0
0
--
--
42.2
21.1
46
32.2
P103 pin 1 – Earth
0
0
--
--
P103 pin 2 – Earth
20.8
10.4
47
32.9
T101 pin 9 – Earth
0
0
--
--
41.2
20.6
47
32.9
P103 pin 1 – Earth
0
0
--
--
P103 pin 2 – Earth
7.4
3.7
47
32.9
T101 pin 9 – Earth
0
0
--
--
Unit shut down, no hazards
Unit shut down, no hazards
-Unit shut down, no hazards
Single fault condition (D133 shorted)
P103 pin 1 – P103 pin 2
-Unit shut down, no hazards
-Unit shut down, no hazards
Single fault condition (R151 shorted)
P103 pin 1 – P103 pin 2
-Unit shut down, no hazards
--
Single fault condition (Q110 pin 1 to pin 2 shorted)
P103 pin 1 – P103 pin 2
0
0
--
--
Unit shut down, no hazards
P103 pin 1 – Earth
0
0
--
--
Unit shut down, no hazards
P103 pin 2 – Earth
0
0
--
--
Unit shut down, no hazards
T101 pin 9 – Earth
0
0
--
--
Unit shut down, no hazards
Single fault condition (C181 shorted)
P103 pin 1 – P103 pin 2
0
0
--
--
Unit shut down, no hazards
P103 pin 1 – Earth
0
0
--
--
Unit shut down, no hazards
P103 pin 2 – Earth
0
0
--
--
Unit shut down, no hazards
T101 pin 9 – Earth
0
0
--
--
Unit shut down, no hazards
Single fault condition (C185 shorted)
P103 pin 1 – P103 pin 2
0
0
--
--
Unit shut down, no hazards
P103 pin 1 – Earth
0
0
--
--
Unit shut down, no hazards
P103 pin 2 – Earth
0
0
--
--
Unit shut down, no hazards
T101 pin 9 – Earth
0
0
--
--
Unit shut down, no hazards
0
--
--
Unit shut down, no hazards
Single fault condition (C106 shorted)
P103 pin 1 – P103 pin 2
TRF No.:IECEN60950_1B
0
TRF originator: SGS Fimko
Page 53 of 82
Report No.:
11009010 001
P103 pin 1 – Earth
0
0
--
--
Unit shut down, no hazards
P103 pin 2 – Earth
0
0
--
--
Unit shut down, no hazards
T101 pin 9 – Earth
0
0
--
--
Unit shut down, no hazards
Single fault condition (D136 shorted)
P103 pin 1 – P103 pin 2
52
26
47
32.9
P103 pin 1 – Earth
0
0
--
--
P103 pin 2 – Earth
4.2
2.1
51
35.7
T101 pin 9 – Earth
0
0
--
--
-Unit shut down, no hazards
-Unit shut down, no hazards
Power supply with DC/AC inverter board: PTB-1806
Normal condition
--
P101 pin1 to pin2
38.8
19.4
47
32.9
P101 pin1 to Earth
0
0
--
--
P101 pin2 to Earth
2.2
1.1
47
32.9
--
P102 pin1 to pin2
42.4
21.2
47
32.9
--
P102 pin1 to Earth
42.0
21.0
47
32.9
--
P102 pin2 to Earth
0.4
0.2
1
0.7
--
P101 pin1 to pin2
0
0
--
--
Unit shut down, no hazards
P101 pin1 to Earth
0
0
--
--
Unit shut down, no hazards
P101 pin2 to Earth
0
0
--
--
Unit shut down, no hazards
P102 pin1 to pin2
0
0
--
--
Unit shut down, no hazards
P102 pin1 to Earth
0
0
--
--
Unit shut down, no hazards
P102 pin2 to Earth
0
0
--
--
Unit shut down, no hazards
P101 pin1 to pin2
38.7
19.4
47
32.9
P101 pin1 to Earth
0
0
--
--
P101 pin2 to Earth
2.2
1.1
46
32.2
--
P102 pin1 to pin2
41.9
21.0
47
32.9
--
P102 pin1 to Earth
42.1
21.1
47
32.9
--
P102 pin2 to Earth
0.4
0.2
1
0.7
--
P101 pin1 to pin2
39.0
19.5
47
32.2
--
P101 pin1 to Earth
0
0
--
--
P101 pin2 to Earth
2.2
1.1
47
32.9
--
P102 pin1 to pin2
42.1
21.1
47
32.9
--
Unit shut down, no hazards
Single fault condition (D103 short)
Single fault condition (C115 short)
-Unit shut down, no hazards
Single fault condition (R115 short)
TRF No.:IECEN60950_1B
Unit shut down, no hazards
TRF originator: SGS Fimko
Page 54 of 82
Report No.:
11009010 001
P102 pin1 to Earth
41.9
20.1
47
32.9
--
P102 pin2 to Earth
0.4
0.2
1
0.7
--
P101 pin1 to pin2
0
0
--
--
Unit shut down, no hazards
P101 pin1 to Earth
0
0
--
--
Unit shut down, no hazards
P101 pin2 to Earth
0
0
--
--
Unit shut down, no hazards
P102 pin1 to pin2
0
0
--
--
Unit shut down, no hazards
P102 pin1 to Earth
0
0
--
--
Unit shut down, no hazards
P102 pin2 to Earth
0
0
--
--
Unit shut down, no hazards
P101 pin1 to pin2
0
0
--
--
Unit shut down, no hazards
P101 pin1 to Earth
0
0
--
--
Unit shut down, no hazards
P101 pin2 to Earth
0
0
--
--
Unit shut down, no hazards
P102 pin1 to pin2
0
0
--
--
Unit shut down, no hazards
P102 pin1 to Earth
0
0
--
--
Unit shut down, no hazards
P102 pin2 to Earth
0
0
--
--
Unit shut down, no hazards
P101 pin1 to pin2
38.4
19.2
47
32.9
P101 pin1 to Earth
0
0
--
--
P101 pin2 to Earth
2.2
1.1
47
32.9
--
P102 pin1 to pin2
42.1
21.1
47
32.9
--
P102 pin1 to Earth
42.3
21.2
47
32.9
--
P102 pin2 to Earth
0.4
0.2
1
0.7
--
Single fault condition (C117 short)
Single fault condition (C132 short)
Single fault condition (C133 short)
-Unit shut down, no hazards
Note(s): Output measured with a 2kΩ non-inductive resistor as load.
2.5
TABLE: limited power source measurement
Limits
P
Measured
Verdict
For main board type A, output connector P308 (to key control board), from pin 1 to earth
According to Table 2B (normal condition), Uoc=5.5V
current (in A)
apparent power (in VA)
8
0.02
Pass
Uoc*5 (27.5)
0.06
Pass
8
0.02
Pass
Uoc*5 (27.5)
0.06
Pass
According to Table 2B (R813 shorted in single fault condition), Uoc=5.5V
current (in A)
apparent power (in VA)
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 55 of 82
Report No.:
11009010 001
According to Table 2B (R817 shorted in single fault condition), Uoc=5.5V
current (in A)
apparent power (in VA)
8
0.02
Pass
Uoc*5 (27.5)
0.06
Pass
According to Table 2B (I805 pin1-4 shorted in single fault condition), Uoc=5.5V
current (in A)
apparent power (in VA)
8
0.02
Pass
Uoc*5 (27.5)
0.06
Pass
According to Table 2B (I802 pin1-2 shorted in single fault condition), Uoc=5.5V
current (in A)
apparent power (in VA)
8
0.02
Pass
Uoc*5 (27.5)
0.06
Pass
For main board type A, output connector P308 (to key control board), from pin 4 to earth
According to Table 2B (normal condition), Uoc=5.2V
current (in A)
apparent power (in VA)
8
0.02
Pass
Uoc*5 (26)
0.06
Pass
8
0.02
Pass
Uoc*5 (26)
0.06
Pass
8
0.02
Pass
Uoc*5 (26)
0.06
Pass
According to Table 2B (R813 shorted in single fault condition), Uoc=5.2V
current (in A)
apparent power (in VA)
According to Table 2B (R817 shorted in single fault condition), Uoc=5.2V
current (in A)
apparent power (in VA)
According to Table 2B (I805 pin1-4 shorted in single fault condition), Uoc=5.2V
current (in A)
apparent power (in VA)
8
0.02
Pass
Uoc*5 (26)
0.06
Pass
According to Table 2B (I802 pin1-2 shorted in single fault condition), Uoc=5.2V
current (in A)
apparent power (in VA)
8
0.02
Pass
Uoc*5 (26)
0.06
Pass
For main board type A, output connector P306 (to speaker), from pin 2,3,4,5 to earth
According to Table 2B (normal condition), Uoc=2.8V
current (in A)
apparent power (in VA)
8
0.02
Pass
Uoc*5 (14)
0.05
Pass
8
0.02
Pass
Uoc*5 (14)
0.05
Pass
8
0.02
Pass
Uoc*5 (14)
0.05
Pass
According to Table 2B (R813 shorted in single fault condition), Uoc=2.8V
current (in A)
apparent power (in VA)
According to Table 2B (R817 shorted in single fault condition), Uoc=2.8V
current (in A)
apparent power (in VA)
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 56 of 82
Report No.:
11009010 001
According to Table 2B (I805 pin1-4 shorted in single fault condition), Uoc=2.8V
current (in A)
apparent power (in VA)
8
0.02
Pass
Uoc*5 (14)
0.05
Pass
According to Table 2B (I802 pin1-2 shorted in single fault condition), Uoc=2.8V
current (in A)
apparent power (in VA)
8
0.02
Pass
Uoc*5 (14)
0.05
Pass
Power supply with DC/AC inverter board: PTB-1806
For +20.5Vdc output of power supply with DC/AC inverter board (output to DC/AC inverter)
According to Table 2B in normal condition, UOC=25V
current (in A)
apparent power (in VA)
8
3
Pass
100
53.5
Pass
8
1.39
Pass
100
29.54
Pass
1)
Pass
1)
Pass
8
1)
Pass
5 * Uoc = 1)
1)
Pass
1)
Pass
1)
Pass
1)
Pass
1)
Pass
1)
Pass
1)
Pass
According to Table 2B in fault condition with D811 short, UOC=22.41V
current (in A)
apparent power (in VA)
According to Table 2B in fault condition with R811 short, UOC=1)
current (in A)
8
apparent power (in VA)
5 * Uoc =
1)
1)
According to Table 2B in fault condition with I802 pin1 open, UOC=
current (in A)
apparent power (in VA)
1)
According to Table 2B in fault condition with I802 pin1-pin2 short, UOC=
current (in A)
8
apparent power (in VA)
5 * Uoc =
1)
1)
According to Table 2B in fault condition with I802 pin4 open, UOC=
current (in A)
8
apparent power (in VA)
5 * Uoc =
1)
According to Table 2B in fault condition with I802 pin3-pin4 short, UOC=1)
current (in A)
8
apparent power (in VA)
5 * Uoc =
1)
For P310 connector (on main board type B, output to speaker)
According to Table 2B in normal condition, pin 1 to earth UOC=2.67V
current (in A)
apparent power (in VA)
8
2.5
Pass
5 * Uoc = 13.35
3.8
Pass
2.5
Pass
According to Table 2B in normal condition, pin 2 to earth UOC=2.67V
current (in A)
TRF No.:IECEN60950_1B
8
TRF originator: SGS Fimko
Page 57 of 82
apparent power (in VA)
Report No.:
5 * Uoc = 13.35
11009010 001
3.8
Pass
8
2.4
Pass
5 * Uoc = 13.35
3.8
Pass
8
2.4
Pass
5 * Uoc = 13.35
3.8
Pass
According to Table 2B in normal condition, pin 3 to earth UOC=2.67V
current (in A)
apparent power (in VA)
According to Table 2B in normal condition, pin 4 to earth UOC=2.67V
current (in A)
apparent power (in VA)
According to Table 2B in fault condition with condition: R811 short/I802 pin1 open/I802 pin1-pin2 short/ I802
pin4 open/I802 pin3-pin4 short, UOC=1)
current (in A)
8
apparent power (in VA)
5 * Uoc =
1)
1)
Pass
1)
Pass
For P307 connector (on main board type B, output to key control board)
According to Table 2B in normal condition, pin 1 to earth UOC=1)
current (in A)
apparent power (in VA)
1)
Pass
1)
Pass
1)
Pass
1)
Pass
8
0.02
Pass
5 * Uoc = 3.96
0.04
Pass
8
0.01
Pass
5 * Uoc = 13.3
0.03
Pass
8
0.01
Pass
5 * Uoc = 13.3
0.03
Pass
8
5 * Uoc =
1)
1)
According to Table 2B in normal condition, pin 2 to earth UOC=
current (in A)
apparent power (in VA)
8
5 * Uoc =
1)
According to Table 2B in normal condition, pin 3 to earth UOC=1.98V
current (in A)
apparent power (in VA)
According to Table 2B in normal condition, pin 4 to earth UOC=2.66V
current (in A)
apparent power (in VA)
According to Table 2B in normal condition, pin 5 to earth UOC=2.66V
current (in A)
apparent power (in VA)
According to Table 2B in fault condition with condition: R811 short/I802 pin1 open/I802 pin1-pin2 short/ I802
pin4 open/I802 pin3-pin4 short, UOC=1)
current (in A)
apparent power (in VA)
1)
Pass
1)
Pass
8
0.9
Pass
5 * Uoc = 25.5
4.19
Pass
8
5 * Uoc =
1)
For USB ports
According to Table 2B in normal condition, UOC=5.1V
current (in A)
apparent power (in VA)
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 58 of 82
Report No.:
11009010 001
According to Table 2B in fault condition with condition: I603 pin5-pin7 short, UOC=5.1V
current (in A)
apparent power (in VA)
8
0.95
Pass
5 * Uoc = 25.5
4.17
Pass
Note(s):
1)
Unit shut down.
2)
Input Voltage is 240Vac, 60Hz
2.6.3.4
TABLE: ground continue test
Location
P
Resistance measured (mΩ) Comments
Unit with Power supply with DC/AC inverter board: PTB-1725
The PE pin of AC inlet to the signal
cable
7
Test current at 25A, for 1 min.
The PE pin of AC inlet to the signal
cable
7
Test current at 40A, for 2 min.
The PE pin of AC inlet to the earth
trace of C802
13
Test current at 25A, for 1 min.
The PE pin of AC inlet to the earth
trace of C802
13
Test current at 40A, for 2 min.
Unit with Power supply with DC/AC inverter board: PTB-1806
AC inlet earth pin to metal
enclosure
15.9
25A, 1min
AC inlet earth pin to C825 earthed
trace
16.7
40A, 2min
AC inlet earth pin to C825 earthed
trace
13.6
25A, 1min
AC inlet earth pin to C808 earthed
trace
17.0
40A, 2min
AC inlet earth pin to C808 earthed
trace
15.1
25A, 1min
Note(s):
2.10.2
Table: working voltage measurement
Location
RMS voltage (V)
P
Peak voltage (V) Comments
Power supply with DC/AC inverter board: PTB-1725
T801 pin 1 to pin 8
273
588
T801 pin 1 to pin 9, 10
269
580
T801 pin 1 to pin 11
261
580
TRF No.:IECEN60950_1B
Max. Vpeak and Vrms of T801
TRF originator: SGS Fimko
Page 59 of 82
Report No.:
T801 pin 1 to pin 12
237
620
T801 pin 1 to pin 13
256
576
T801 pin 4 to pin 8
214
388
T801 pin 4 to pin 9, 10
216
396
T801 pin 4 to pin 11
217
428
T801 pin 4 to pin 12
165
288
T801 pin 4 to pin 13
222
464
T801 pin 6 to pin 8
215
420
T801 pin 6 to pin 9, 10
216
396
T801 pin 6 to pin 11
213
376
T801 pin 6 to pin 12
167
312
T801 pin 6 to pin 13
213
388
T801 pin 7 to pin 8
214
372
T801 pin 7 to pin 9, 10
212
376
T801 pin 7 to pin 11
214
388
T801 pin 7 to pin 12
165
268
T801 pin 7 to pin 13
214
392
I802 pin 1 – pin 3
216
376
I802 pin 1 – pin 4
216
376
I802 pin 2 – pin 3
216
376
I802 pin 2 – pin 4
216
376
11009010 001
Power supply with DC/AC inverter board: PTB-1806
T801 pin 1 to pin 6
273
524
Highest Vrms of T801
T801 pin 1 to pin 7, 8
268
532
Highest Vpk of T801
T801 pin 1 to pin 9
261
524
T801 pin 1 to pin 10
252
516
T801 pin 3 to pin 6
217
376
T801 pin 3 to pin 7, 8
217
396
T801 pin 3 to pin 9
217
436
T801 pin 3 to pin 10
220
472
T801 pin 4 to pin 6
217
428
T801 pin 4 to pin 7, 8
215
416
T801 pin 4 to pin 9
214
388
T801 pin 4 to pin 10
214
396
T801 pin 5 to pin 6
213
372
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 60 of 82
Report No.:
T801 pin 5 to pin 7, 8
213
376
T801 pin 5 to pin 9
215
388
T801 pin 5 to pin 10
217
396
C808 primary to secondary
213
372
I802 pin 1 to pin 3
216
376
I802 pin 1 to pin 4
216
376
I802 pin 2 to pin 3
216
376
I802 pin 2 to pin 4
216
376
11009010 001
Note(s): Input Voltage is 240Vac, 60Hz
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)
P
cl
(mm)
Required
dcr (mm)
dcr
(mm)
2.5
2.5
Power supply with DC/AC inverter board: PTB-1725
Primary components (with
10N) to earthed metal
enclosure
420
250
2.0
T803 to metal stud of earthed
metal enclosure
Primary traces to earthed
trace of SPS
2.5
5.0
420
250
2.0
5.0
See below
2.5
See below
Near C803
2.5
2.5
Near T802
2.5
2.5
Under C802
3.3
3.3
Under C808
2.5
2.5
Near C806
2.7
2.7
D815 trace to earthed trace
2.8
2.8
Line/neutral trace to earthed
trace
2.0
2.5
Primary traces to secondary
trace of SPS
420
250
4.0
See below
5.0
See below
Under I802
4.5
5.0
Under C805
7.5
7.5
Under C836
7.6
7.6
Under T801
Between fuse two ends
1).
TRF No.:IECEN60950_1B
588
273
4.6
7.6
5.8
7.6
420
250
1.5
6.0
2.5
6.0
TRF originator: SGS Fimko
Page 61 of 82
Primary trace before fuse 1).
420
250
Report No.:
1.5
2.9
11009010 001
2.5
2.9
2.5
See above
Power supply with DC/AC inverter board: PTB-1806
Primary traces → earthed
trace of SPS
420
250
2.0
See above
Under C820
6.8
6.8
Under C825
6.8
6.8
Near C819
6.7
6.7
Line/neutral trace to earthed
trace
4.0
4.7
Primary traces → secondary
trace of SPS
420
250
4.0
See above
5.0
See above
Under I802
5.0
6.1
Under C808
7.3
7.3
Under T801
Between fuse two ends
1).
Primary trace before fuse
1).
532
273
4.4
6.9
5.8
6.9
420
250
1.5
7.2
2.5
7.2
420
250
1.5
2.5
2.5
4. 0
Note(s):
1. Functional insulation, see clause 5.3.4 a).
2. Other functional insulation according to sub-clause 5.3.4 c).
For Power supply with DC/AC inverter board: PTB-1725
- There is one cut slot (1.2mm x 11.1mm) between Line/Neutral trace and earthed trace of AC inlet.
- There is one cut slot (1.4mm x 7.9mm) under I802 primary and secondary race.
- Glued components: C836, C805, C801.
- There is a mylar sheet (170mm x 210mm min.) between component side of power supply with DC/AC
inverter board and metal enclosure type A.
For Power supply with DC/AC inverter board: PTB-1806
- There are two L type slots (1.2mm x 8.5mm x 7.1mm) between Line/Neutral trace.
- There is one cut slot (1.6mm x 7.9mm) under I802 primary and secondary race.
- Glued component: C805.
- There is a mylar sheet (170mm x 210mm min.) between component side of power supply with DC/AC
inverter board and metal enclosure type B.
2.10.5
TABLE: distance through insulation measurements
P
Distance through insulation di at/of:
U r.m.s.
(V)
Test voltage
(V)
Required di
(mm)
di
(mm)
Photo coupler (reinforced insulation)
250
3000
0.4
1)
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 62 of 82
Report No.:
11009010 001
Note(s):
1)
See appended table 1.5.1 for approved component source details.
4.5.1
TABLE: maximum temperatures
P
test voltage (V) .............................................: a) 90V

b) 264V
t1 (°C) ..........................................................: --

t2 (°C) ..........................................................: --

Maximum temperature T of part/at:
Test voltage
T (°C)
a)
allowed Tmax (°C)
b)
--
Power supply with DC/AC inverter board: PTB-1725
AC inlet near line pin
46.7
46.8
70
C803 body
53.7
51.9
85
T802 coil
65.8
55.4
130
T802 core
61.5
53.9
130
T803 coil
66.7
57.1
130
C801 body
66.9
60.5
105
PCB near Q801
80.1
77.8
105
T801 core
62.1
58.5
110
T801 coil
76.0
77.4
110
I802 body
63.0
62.0
100
T101 coil
88.5
89.3
130
T101 core
77.3
79.0
130
T102 coil
92.1
92.2
130
PCB near D802
81.6
83.5
105
Plastic enclosure outside near T101
50.4
51.1
95
Plastic enclosure inside near T101
58.8
60.0
--
Ambient
40.0
40.0
--
Ambient during test
23.4
21.9
--
Power supply with DC/AC inverter board: PTB-1806
Appliance Inlet near line pin
49.4
48.8
70
C819 body
64.7
59.4
85
T802 coil
68.8
60.7
130
C805 body
69.4
64.3
85
T801 coil (class B)
93.8
94.7
110
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 63 of 82
Report No.:
11009010 001
T801 core (class B)
88.0
89.2
110
C808 body
77.5
75.6
85
I802 body
71.8
70.3
100
PCB near R808
91.3
71.8
105
T101 coil (DC/AC inverter)
78.2
77.9
130
T101 core (DC/AC inverter)
77.8
77.7
130
PCB near I306 (main board)
78.1
77.9
105
Plastic enclosure inside
60.4
60.1
--
Plastic enclosure outside
56.1
56.1
95
LCD Panel
50.1
50.1
--
Ambient
40.0
40.0
--
Ambient during test
26.5
26.4
--
Power supply with DC/AC inverter board: PTB-1725 with USB port
Appliance Inlet near line pin
51.5
50.6
70
C803 body
64.2
58.5
85
T802 coil
81.5
63.8
130
T803 coil
87.1
65.9
130
C801 body
78.4
67.4
85
T801 coil (class B)
98.6
100.7
110
T801 core (class B)
97.6
100.0
110
I802 body
72.5
69.8
100
PCB under R801
104.4
80.1
105
T102 coil
105.9
104.7
130
T102 core
102.1
101.8
130
PCB near I306 (main board)
69.0
68.5
105
Plastic enclosure inside
58.4
57.9
--
Plastic enclosure outside
54.6
54.1
95
LCD Panel
51.4
51.6
--
Ambient
40.0
40.0
--
Ambient during test
26.3
26.3
--
Temperature T of winding:
R1
(Ω)
R2
(Ω)
T
(°C)
allowed
Tmax (°C)
insulation
class
Note(s):
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 64 of 82
Report No.:
11009010 001
1. The temperatures were measured under the worse case normal mode defined in 1.2.2.1 and as described
in sub-clause 1.6.2 at voltages as described above.
2. With a specified ambient temperature of 40°C.
3. The maximum temperatures are calculated as follows:
Winding components (with safety isolation):
- Class B → Tmax = 120 °C - 10 °C = 110°C
4.5.2
TABLE: ball pressure test of thermoplastic parts
P
allowed impression diameter (mm) .................. : ≤ 2 mm

Part
Test temperature
(°C)
Impression diameter
(mm)
125
1.2
125
1.5
Power supply with DC/AC inverter board: PTB-1725
Bobbin of T802 and T803 / Nan Ya, type 1403G3 (0.75mm)
Power supply with DC/AC inverter board: PTB-1806
E I Dupont, type FR530L+ of transformer T801
Note(s):
4.6.1, 4.6.2 Table: enclosure openings
Location
P
Size (mm)
Comments
Internal metal enclosure type A
Top
∅4.5mm Numerous circle openings, cover area 25mm
x 315mm.
Rear (left and right side) 2)
∅4.5mm Numerous circle openings, cover area 145mm
x 55mm (left side) and 145mm x 55mm (right
side).
Left Side
∅4.5mm Numerous circle openings at an area 23mm
35mm.
Right Side
∅4.5mm Numerous circle openings at an area 23mm
35mm.
Bottom
Ø1.8mm, Numerous circle openings at an area 312mm
Central to central: 5.0mm, x 35mm.
Thickness: 0.81mm
External plastic enclosure type A
Top
3.6mm x 40mm Numerous rectangle openings cover area
40mm 340mm.
Rear
N/A No openings.
Side
N/A No openings.
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 65 of 82
Bottom
Report No.:
11009010 001
3.9mm x 25mm Numerous rectangle openings cover area
25mm x 130mm and 25mm x 33mm (two
blocks).
Internal metal enclosure type B
Top
∅4.5mm Numerous circle openings, cover area
34.5mm x 315mm.
Rear (left and right side) 2)
∅4.5mm Numerous circle openings, cover area 145mm
x 55.5mm.
Left Side
∅4.5mm Numerous circle openings at an area 25mm
35mm.
Right Side
∅4.5mm Numerous circle openings at an area 25mm
35mm.
Bottom
Ø1.8mm, Numerous circle openings at an area 230mm
Central to central: 5.0mm, x 27mm and 25mm x 27mm.
Thickness: 0.81mm
External plastic enclosure type B
Top
2.6mm x 40mm Numerous rectangle openings cover area
40mm 340mm.
Rear
N/A No openings.
Side
N/A No openings.
Bottom
3.6m x 25.6mm Numerous rectangle openings cover area
25.6mm x 130mm and 25.6mm x 31mm (two
blocks).
Note(s):
1) The internal metal enclosure was considered as fire enclosure.
2) According to user’s manual, the unit can’t adjust downward, therefore the rear opening considered as
side opening to prevent subjects drop into fire enclosure.
3) The construction of alternative plastic enclosure type C is similar to enclosure shape type A except USB
part.
4.7
Part
Table: resistance to fire
Manufacturer of material
N/A
Type of material
Thickness
(mm)
Flammability
class
Note(s): Internal metal enclosure was considered as fire enclosure.
5.1.6
Condition
TABLE: touch current measurement
L→ terminal A N → terminal A
(mA)
(mA)
P
Limit
(mA)
Comments
Power supply with DC/AC inverter board: PTB-1725
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 66 of 82
Report No.:
11009010 001
System ON (Fuse
in)
1.7
1.7
3.5
To metal enclosure/output connector,
switch “e” opened.
System ON (Fuse
out)
0.02
3.4
3.5
To metal enclosure/output connector,
switch “e” opened.
System ON (Fuse
in)
0.01
0.01
0.25
To plastic enclosure with metal foil,
switch “e” opened.
Power supply with DC/AC inverter board: PTB-1806
System ON (Fuse
in)
0.19
0.20
3.5
To metal enclosure, switch “e”
opened.
System ON (Fuse
in)
0.19
0.20
3.5
To earthed output connector, switch
“e” opened.
System ON (Fuse
in)
0.01
0.01
0.25
To plastic enclosure with metal foil,
switch “e” closed.
Note(s):
Input voltage:
Input frequency:
264V
60Hz
Overall capacity:
C802=C805=C808=C836=C838=C839=4700pF (Power supply with DC/AC inverter board: PTB-1725);
C808=C820=C825=4700pF (Power supply with DC/AC inverter board: PTB-1806)
5.2
TABLE: electric strength tests and impulse tests
Test voltage applied between:
P
Test voltage (V)
Breakdown
Power supply with DC/AC inverter board: PTB-1725
Unit: primary and secondary
DC 4242
No
Unit: primary and Earth
DC 2651
No
T801: primary and secondary
AC 3000
No
T801: primary and core
AC 1875
No
T801: secondary and core
AC 1875
No
2 layers of insulation tape
AC 3000
No
Mylar sheet
AC 1500
No
Power supply with DC/AC inverter board: PTB-1806
Unit: primary and secondary
DC 4242
No
Unit: primary and earth
DC 2550
No
T801: primary and secondary
AC 3000
No
T801: primary and core
AC 1803
No
T801: secondary and core
AC 1803
No
Two layers of insulation tape of T801
AC 3000
No
Mylar sheet
AC 1500
No
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 67 of 82
Report No.:
11009010 001
Note(s):
5.3
No.
TABLE: fault condition tests
P
ambient temperature (°C) ...................................... : 25°C, if not otherwise stated

model/type of power supply ................................... : See below

manufacturer of power supply ............................... : See append table 1.5.1

rated markings of power supply ............................. : See append table 1.5.1

Component no.
Fault
Test
voltage (V)
Test
time
Fuse
no.
Fuse
Result
current (A)
Power supply with DC/AC inverter board: PTB-1725
1
T801 pin 11 to
pin 13
s-c
240
10 min
F801
0.08-0.14 Unit shut down, no
components damaged, no
hazards
2
T801 pin 11 to
pin 10
s-c
240
10 min
F801
0.08-0.15 Unit shut down, no
components damaged, no
hazards
3
T801 pin 9 to pin
8
s-c
240
10 min
F801
0.08-0.15 No display, no components
damaged, no hazards
4
T801 pin 1 to pin
4
s-c
240
10 min
F801
0.08-0.2 Unit shut down, no
components damaged, no
hazards
5
T801 pin 6 to pin
7
s-c
240
10 min
F801
0.08 Unit shut down, no
components damaged, no
hazards
6
D805
s-c
240
1 sec
F801
0.08-0.12 No display, no components
damaged, no hazards
7
D812
s-c
240
10 min
F801
0.08-0.12 Unit shut down, no
components damaged, no
hazards
8
D807
s-c
240
10 min
F801
0.08-0.13 Unit shut down, no
components damaged, no
hazards
9
C815
s-c
240
10 min
F801
0.08-0.14 Unit shut down, no
components damaged, no
hazards
10
C812
s-c
240
10 min
F801
0.08-0.14 Unit shut down, no
components damaged, no
hazards
11
C823
s-c
240
10 min
F801
0.08-0.12 Unit shut down, no
components damaged, no
hazards
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 68 of 82
Report No.:
11009010 001
12
I802 pin 4
o-c
240
10 min
F801
0.08 No display, no components
damaged, no hazards
13
I802 pin 1 to pin
2
s-c
240
10 min
F801
0.08 No display, no components
damaged, no hazards
14
I802 pin 3 to pin
4
s-c
240
10 min
F801
0.08-0.12 No display, no components
damaged, no hazards
15
Q801 pin G to pin
D
s-c
240
1 sec
F801
16
Q801 pin G to pin
S
s-c
240
10 min
F801
0.2 No display, no components
damaged, no hazards
17
Q801 pin D to pin
S
s-c
240
1 sec
F801
0.2 No display, no components
damaged, no hazards
18
C801
s-c
240
1 sec
F801
-- F801 damaged, no hazards.
19
D802
s-c
240
1 sec
F801
-- F801 damaged, no hazards.
20
D813
s-c
240
10 min
F801
21
T801 pin 13 to
pin 8 (after D805)
o-l
240
6.5 hrs
F801
-- Overload to 5.0A, no
components damaged, T801
coil = 148°C, T801 core =
111°C, ambient = 25°C, no
hazards.
22
T801 pin 11 to
pin 8 (after D807)
o-l
240
7.5 hrs
F801
-- Overload to 6.0A, no
components damaged, T801
coil = 136°C, T801 core =
126°C, ambient = 25°C, no
hazards.
23
T801 pin 10 to
pin 8(after D812)
o-l
240
7.0 hrs
F801
-- Overload to 8.0A, no
components damaged, T801
coil = 138°C, T801 core =
130°C, ambient = 22°C, no
hazards.
0.02 Unit shut down, no
components damaged, no
hazards
0.02 No display, no components
damaged, no hazards
Power supply with DC/AC inverter board: PTB-1806
24
D808
s-c
240
1 sec
F801
-- F801 opened, no hazards.
25
C805
s-c
240
1 sec
F801
-- F801 opened, no hazards.
26
Q803 (D-S)
s-c
240
30 min
F801
0.04 Unit shutdown, I801 and
R813 damaged, no hazards.
27
Q803 (D-G)
s-c
240
30 min
F801
0.04 Unit shutdown, I801
damaged, no hazards.
28
R811
s-c
240
30 min
F801
0.04 Unit shutdown, I801
damaged, no hazards.
29
I802 pin 3 to pin
4
s-c
240
30 min
F801
0.05 Unit shutdown, Internal
protection operated (I801), no
hazards.
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 69 of 82
Report No.:
11009010 001
30
I802 pin 1 to pin
2
s-c
240
30 min
F801
0.05 Unit shutdown, Internal
protection operated (I801), no
hazards.
31
I802 pin 4
o-c
240
30 min
F801
0.04 Unit shutdown, Internal
protection operated (I801), no
hazards.
32
I802 pin 1
o-c
240
30 min
F801
0.05 Unit shutdown, Internal
protection operated (I801), no
hazards.
33
D809
s-c
240
30 min
F801
0.04 Unit shutdown, Internal
protection operated (I801), no
hazards.
34
D810
s-c
240
30 min
F801
0.06 Unit shutdown, Internal
protection operated (I801), no
hazards.
35
T801 pin 4 to pin
5
s-c
240
30 min
F801
0.05 Unit shutdown, Internal
protection operated (I801), no
hazards.
36
T801 pin 10 to
pin 6
s-c
240
30 min
F801
0.05 Unit shutdown, Internal
protection operated (I801), no
hazards.
37
T801 pin 8,7 to
pin 6
s-c
240
30 min
F801
0.06 Unit shutdown, Internal
protection operated (I801), no
hazards.
38
T801 pin 1 to pin
3
s-c
240
30 min
F801
0.07 Unit shutdown, no
components damaged, no
hazards.
39
T801 pin 10 to
pin 8,7
s-c
240
30 min
F801
0.1 Unit shutdown, no
components damaged, no
hazards.
40
I801 pin 3 to pin
2
s-c
240
30 min
F801
0.08 I801 and I802 damaged, no
hazards.
41
+20.5Vdc output
s-c
240
30 min
F801
0.04 Unit shutdown, Internal
protection operated (I801), no
hazards.
42
+5Vdc ouptut
s-c
240
30 min
F801
0.04 Unit shutdown, Internal
protection operated (I801), no
hazards.
43
T801 pin 7,8 to
pin 6 (after D810)
o-l
240
7 hrs
F801
0.67 When overloaded to 5.8A
unit shutdown. Temp was
stable at 5.4A. Max. temp of
T801 coil=79.8ºC, T801
core=71.2ºC, I802
body=39.7ºC,
Ambient=26.3ºC, no hazard.
Complied sub clause 5.3.8.
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 70 of 82
44
T801 pin 10 to
pin 6 (after D809)
45
o-l
Report No.:
11009010 001
240
15.5 hrs
F801
0.66 When overloaded to 2.8A
unit shutdown. Temp was
stable at 2.6A. Max. Temp of
T801 coil=74.4ºC, T801
core=67.2ºC, I802
body=37.6ºC,
Ambient=27.8ºC, no hazard.
Complied sub clause 5.3.8.
Ventilation
Blocke
openings (plastic
d
enclosure type A)
240
3 hrs
F801
0.65 Temp. was stabled. T801
coil=64.5°C, T801
core=46.6°C, T101
coil=78.6°C, T102
coil=83.2°C,
ambient=21.8°C, no hazards.
46
Ventilation
opening (plastic
enclosure type B)
blocke
d
240
1 hr 20
min
F801
0.42 Temperatures were stabled.
Max. temp. of T801
coil=84.8°C, T801
core=79.4°C, I802
body=61.3°C,
ambient=26.1°C.
47
Ventilation
opening (plastic
enclosure type A
with USB port
blocke
d
240
1 hr 50
min
F801
0.57 Temperatures were stabled.
Max. temp. of T801
coil=94.1°C, T801
core=93.6°C, I802
body=64.6°C,
ambient=26.4°C.
Note(s):
1). In fault column, where s-c=short-circuited, o-c=open-circuited, o-l = overload.
2). For fuse opened conditions were tested with each source of fuse.
3). Temp. limited of transformer (class B) according to table C.1 is 175°C -(40°C -25°C)=160°C.
C.2
Safety isolation transformer
P
Construction details:
Transformer part name: T801 of Power supply with DC/AC inverter board: PTB-1725
Manufacturer: See appended table 1.5.1
Type:
See appended table 1.5.1
Recurring peak voltage
588V
Required clearance for reinforced insulation
(from table 2H and 2J)
4.0mm+0.6mm
Effective voltage rms
273V
Required creepage distance for reinforced insulation
(from table 2L with linear interpolation)
5.8
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 71 of 82
Report No.:
11009010 001
Measured min. creepage distance
Location
inside (mm)
outside (mm)
prim-sec
6.4
6.4
prim-core
3.2
3.2
sec-core
3.2
3.2
prim-prim
--
--
Measured min. clearances
Location
inside (mm)
outside (mm)
prim-sec
6.4
6.4
prim-core
3.2
3.2
sec-core
3.2
3.2
prim-prim
--
--
Construction:
Concentric windings on ETD-34 (3C90/TP4/PC40) type core (horizontal orientation), three layers insulation
tape between primary and secondary windings. Three layers of insulation tape are wrapped on external core
surface. Core is considered as floating part. Distance tape is 3.2mm on both sides of transformer bobbin.
Winding ends additionally fixed with tape, outer winding is primary. Tubing on all winding exit ends are leaded
above the distance tape.
Pin numbers
Prim.
6-7, 1-3-4
Sec.
13-11-10, 9-8
Bobbin
Material
Phenolic, Chang Chun, T375J, V-0, 150°C
Thickness
min. 0.8mm
Electric strength test
With 3000 V a.c. after humidity treatment
Result
C.2
Pass
Safety isolation transformer
P
Construction details:
Transformer part name: T801 of power supply with DC/AC inverter board: PTB-1806
Manufacturer: See appended table 1.5.1
Type:
See appended table 1.5.1
TRF No.:IECEN60950_1B
TRF originator: SGS Fimko
Page 72 of 82
Report No.:
11009010 001
Remark: All sources of T801 are identical except for model name and manufacture.
Recurring peak voltage
532
Required clearance for reinforced insulation
(from table 2H and 2J)
4.4mm
Effective voltage rms
273
Required creepage distance for reinforced insulation
(from table 2L with linear interpolation)
5.8mm
Measured min. creepage distance
Location
inside (mm)
outside (mm)
prim-sec
6.4
22.0 (pin to pin);
6.0 (winding to pin)
prim-core
3.0
5.8 (pin to core)
sec-core
3.2
5.8 (pin to core)
prim-prim
--
--
Measured min. clearances
Location
inside (mm)
outside (mm)
prim-sec
6.4
22.0 (pin to pin);
6.0 (winding to pin)
prim-core
3.0
5.8 (pin to core)
sec-core
3.2
5.8 (pin to core)
prim-prim
--
--
Construction:
Concentric windings on bobbin (horizontal type core). Three layers insulation tape around outer winding
(consider as primary). Three layers insulation tape between primary winding and secondary winding. The core
is considered as floating part. Distance tape of bobbin: 3.0mm min. on primary side winding (N1, N5); 3.2mm
min. on primary side winding (N6) and all secondary side winding; 3.5mm min. on primary side winding (N2,
N3, N4). The bottom side of bobbin (near primary or secondary pin) is further cover with one layer insulation
tape. Side of core near primary or secondary pin is further cover with two layers of insulation tape. Tubing on all
winding exit ends are leaded above the distance tape. Pin 2 cut off.
Pin numbers
Prim.
1-2-3, 4-5
Sec.
10-9-8, 7-6
Bobbin
Material
TRF No.:IECEN60950_1B
EI Dupont, FR530L+, V-0, 155°C
TRF originator: SGS Fimko
Page 73 of 82
Thickness
Report No.:
11009010 001
min. 0.8mm
Electric strength test
With 3000 V a.c. after humidity treatment
Result
TRF No.:IECEN60950_1B
Pass
TRF originator: SGS Fimko
Page 74 of 82
Report No.:
11009010 001
National Differences
Clause
Requirement − Test
TRF No.:IECEN60950_1B
Result – Remark
Verdict
TRF originator: SGS Fimko
Page 75 of 82
Report No.:
11009010 001
National Differences
Clause
Result – Remark
Requirement − Test
APPENDIX Australian National Differences according to CB Bulletin No. 110A, June 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.
N/A
1.2.12.201
After the definition of 1.2.12.15, add the following: Added.
N/A
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.
N/A
Add the following to the end of first and third dash Added.
items:
N/A
"or the relevant Australian/New Zealand
Standard."
1.5.2
"or the relevant Australian/New Zealand
Standard."
2.1
Delete the Note.
Deleted.
N/A
3.2.3
Delete Note 2.
Deleted.
N/A
3.2.5
Modify Table 3B as follows:
Modified.
N/A
Rated current of
equipment A
Over 0.2 up to
and including 3
Nominal
crosssectional
area mm2
AWG or kcmil
(cross-sectional
area in mm2)
see note 2
0.51)
18 [0.8]
Australian National Differences according to CB Bulletin No. 110A, June 2006
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Clause
Result – Remark
Requirement − Test
Over 3 up to and
including 7.5
0.75
16 [1.3]
Over 7.5 up to
and including 10
(0.75)2) 1.00
16 [1.3]
Over 10 up to
and including 16
(1.0)3) 1.5
14 [2]
Verdict
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.
N/A
", or AS/NZS 2211.1"
4.7
Add the following paragraph:
See below.
N/A
Add the following after clause 4.7.3.6:
Added.
N/A
4.7.201 Resistance to fire - Alternative tests
However, equipment under
test and materials and
components in compliance
with requirements of
IEC 60950-1. Alternative test
methods were not considered.
General
See above.
For alternative tests refer to clause 4.7.201.
4.7.201
4.7.201.1
Parts of non-metallic material shall be resistant to
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
Australian National Differences according to CB Bulletin No. 110A, June 2006
N/A
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Clause
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Verdict
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
1750 mm3, integrated circuits, transistors and
optocoupler packages, if these components
are mounted on material flammability
category FV-1 or better according to AS/NZS
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.
See above.
N/A
See above.
N/A
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
Australian National Differences according to CB Bulletin No. 110A, June 2006
Page 78 of 82
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National Differences
Clause
Requirement − Test
Result – Remark
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:
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
Australian National Differences according to CB Bulletin No. 110A, June 2006
Verdict
Page 79 of 82
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Clause
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Verdict
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 See above.
N/A
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
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
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.
For PCB material refer to table
1.5.1 of IEC 60950-1 test
report.
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
Australian National Differences according to CB Bulletin No. 110A, June 2006
N/A
Page 80 of 82
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National Differences
Clause
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Result – Remark
Verdict
(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
supplied is disconnected.
6.2.2
Add the following after the first paragraph:
No TNV circuit.
N/A
No TNV circuit.
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.
Australian National Differences according to CB Bulletin No. 110A, June 2006
Page 81 of 82
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Clause
Result – Remark
Requirement − Test
Verdict
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.
No TNV circuit.
N/A
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 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. 110A, June 2006
N/A
Page 82 of 82
Report No.:
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National Differences
Clause
Requirement − Test
Result – Remark
APPENDIX Korean National Differences according to CB Bulletin No. 110A, June 2006
(K60950)
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.
1.5.101
Addition:
Plugs for the connection of the apparatus to the
supply mains shall comply with the Korean
requirement (KSC 8305).
7
Addition: EMC
The apparatus shall comply with the relevant
CISPR standards.
No power supply cords
provided.
N/A
Compliance shall be evaluated
during national approval.
N/A
Korean National Differences according to CB Bulletin No. 110A, June 2006
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