QUINT4-PS/1AC/24DC/5: Power Supply Unit

QUINT4-PS/1AC/24DC/5
Power supply unit
Data sheet
107099_en_01 © PHOENIX CONTACT 2018-09-03
1 Description
QUINT POWER power supplies with SFB Technology and
preventive function monitoring ensure superior system Technical data (short form)
availability. Input voltage range 100 V AC ... 240 V AC
-15 % ... +10 %
Powerful Mains buffering ≥ 24 ms (120 V AC)
≥ 32 ms (230 V AC)
– SFB technology: 6 times the nominal current for 15 ms
Nominal output voltage (UN) 24 V DC
– Power reserves:
Setting range of the output voltage 24 V DC ... 29.5 V DC
Static boost of up to 125% (PN) for a sustained period (USet)
Dynamic boost of up to 200% (PN) for 5 s Nominal output current (IN) 5A
Static Boost (IStat.Boost) 6.25 A
Robust Dynamic Boost (IDyn.Boost) 10 A (5 s)
Selective Fuse Breaking (ISFB) 30 A (15 ms)
– Mains buffering ≥ 20 ms Output power (PN) 120 W
– High degree of electrical immunity, thanks to integrated Output power (PStat. Boost) 150 W
Output power (PDyn. Boost) 240 W
gas-filled surge arrester (6 kV)
Efficiency typ. 88.8 % (120 V AC)
typ. 89.2 % (230 V AC)
Preventive
Residual ripple < 30 mVPP
– Comprehensive signaling: MTBF (IEC 61709, SN 29500) > 930000 h (40 °C)
Analog signal, digital signal, relay contact, LED bar Ambient temperature (operation) -25 °C ... 70 °C
graph -40°C (startup type tested)
> 60 °C Derating: 2.5 %/K
Can be ordered pre-configured Dimensions W/H/D 36 mm / 130 mm / 125 mm

Weight 0.7 kg
– Perform configuration online and order 1 or more units
All technical specifications are nominal values and refer to a room temperature of 25 °C and 70 % relative
humidity at 100 m above sea level.
2 Table of contents
1 Description .............................................................................................................................. 1
2 Table of contents ..................................................................................................................... 2
3 Ordering data .......................................................................................................................... 3
4 Technical data ......................................................................................................................... 5
5 Safety and installation notes .................................................................................................. 16
6 High-voltage test (HIPOT) ..................................................................................................... 17
7 Structure of the power supply ................................................................................................ 19
8 Mounting/removing the power supply .................................................................................... 22
9 Device connection terminal blocks ........................................................................................ 25
10 Output characteristic curves .................................................................................................. 27
11 Configuring the power supply ................................................................................................ 30
12 Boost currents ....................................................................................................................... 31
13 SFB technology ..................................................................................................................... 33
14 Signaling................................................................................................................................ 37
15 Operating modes ................................................................................................................... 45
16 Derating................................................................................................................................. 47
107099_en_01 PHOENIX CONTACT 2 / 50

3 Ordering data
Description Type Order No. Pcs./Pkt.

Primary-switched QUINT POWER power supply with free QUINT4-PS/1AC/24DC/5 2904600 1
choice of output characteristic curve, SFB (selective fuse
breaking) technology, and NFC interface, input: 1-
phase, output: 24 V DC/5 A
One or more of the primary-switched QUINT POWER power supply with SFB Technology (selective fuse
breaking) versions configured online can now be ordered using the following web code: phoenixcontact.net/
webcode/#0852
Accessories Type Order No. Pcs./Pkt.

Universal wall adapter for securely mounting the power UWA 182/52 2938235 1
supply in the event of strong vibrations. The power supply
is screwed directly onto the mounting surface. The
universal wall adapter is attached at the top/bottom.
2-piece universal wall adapter for securely mounting the UWA 130 2901664 1
power supply in the event of strong vibrations. The profiles
that are screwed onto the side of the power supply are
screwed directly onto the mounting surface. The universal
wall adapter is attached on the left/right.
Assembly adapter for QUINT-PS... power supply on S7- QUINT-PS-ADAPTERS7/1 2938196 1
300 rail
Near Field Communication (NFC) programming adapter TWN4 MIFARE NFC USB 2909681 1
with USB interface for the wireless configuration of NFC- ADAPTER
capable products from PHOENIX CONTACT with
software. No separate USB driver is required.
Type 2/3 surge protection, consisting of protective plug PLT-SEC-T3-230-FM-UT 2907919 5
and base element, with integrated status indicator and
remote signaling for single-phase power supply networks.
Nominal voltage 230 V AC/DC.
Type 3 surge protection, consisting of protective plug and PLT-SEC-T3-24-FM-UT 2907916 5
base element, with integrated status indicator and remote
signaling for single-phase power supply networks.
Type 2/3 surge protection, consisting of protective plug PLT-SEC-T3-230-FM-PT 2907928 5
and base element, with integrated status indicator and
remote signaling for single-phase power supply networks.
Type 3 surge protection, consisting of protective plug and PLT-SEC-T3-24-FM-PT 2907925 5
base element, with integrated status indicator and remote
signaling for single-phase power supply networks.

Accessories Type Order No. Pcs./Pkt.

Multi-channel electronic device circuit breaker for CBMC E4 24DC/1-4A NO 2906031 1
protecting four loads at 24 V DC in the event of overload
and short circuit. With electronic locking of the set nominal
currents. For installation on DIN rails.
Multi-channel electronic circuit breaker with IO-Link CBMC E4 24DC/1-4A+ IOL 2910410 1
interface for protecting four loads at 24 V DC in the event
of overload and short circuit. With electronic locking of the
set nominal currents. For installation on DIN rails.
The range of accessories is being continuously extended. The current range of accessories can be found in
the download area for the product.

4 Technical data
Input data
Unless otherwise stated, all data applies for 25°C ambient temperature, 230 V AC input voltage, and nominal
output current (IN).
Input voltage range 100 V AC ... 240 V AC -15 % ... +10 %

110 V DC ... 250 V DC -18 % ... +40 %
Electric strength, max. 300 V AC 60 s
Frequency range (fN) 50 Hz ... 60 Hz -10 % ... +10 %
Frequency (fR) for railway power supply systems 16.7 Hz (acc. to EN 50163)
Railway power supply systems can be operated at 16.7 Hz. Use conditions and technical data on request.
Current draw typ. 1.7 A (100 V AC)

1.5 A (120 V AC)
0.9 A (230 V AC)
0.8 A (240 V AC)
1.6 A (110 V DC)
0.7 A (250 V DC)
The specified values for current consumption apply for operation in the static boost (PN x 125%).
Discharge current to PE < 3.5 mA

typical 1.1 mA (264 V AC, 60 Hz)
Mains buffering ≥ 24 ms (120 V AC)
≥ 32 ms (230 V AC)
Switch-on time < 500 ms
Typical response time from SLEEP MODE 300 ms
Protective circuit Transient surge protection Varistor, gas-filled surge arrester
Switch-on current surge limitation typical after 1 ms 14 A
Inrush surge current I2t < 0.3 A2s
Input fuse slow-blow, internal 6.3 A
During the first few microseconds, the current flow into the filter capacitors is excluded.
The SCCR value (short-circuit current rating) of the power supply unit corresponds to the SCCR value of the
backup fuse (see input protection table).
The external backup fuse must be approved for the (AC) supply voltage used and the voltage level.

Input protection , AC ( to be connected externally upstream )

Input current IIn Neozed fuse
Circuit breaker Power switch
Input protection or equivalent
≤ 13 x IIn
Characteristics A B C D K gG
(maximum magnetic tripping)
4A - - -    
6A - -     
8A -      
10 A -      
13 A       
16 A       
Electric strength of the insulation
Housing
Input Signaling
(+)
L
N B
(-)
B
A D
PE Output
+
A B C D
Type test (IEC/EN 60950-1) 2.5 kV AC 4 kV AC 0.5 kV DC 0.5 kV DC
Production test 2 kV AC 2 kV AC 0.5 kV DC 0.5 kV DC
Field test (with gas-filled surge arrester) 0.8 kV AC 0.8 kV AC 0.5 kV DC 0.5 kV DC
1.1 kV DC 1.1 kV DC
Field test (gas-filled surge arrester de-contacted) 2 kV AC 2 kV AC 0.5 kV DC 0.5 kV DC
2.83 kV DC 2.83 kV DC
POWER factor
1,0
Power Factor
0,9
0,8
0,7
0,6
0,5 = UIn: 120 V AC/UOut: 24 V DC
= UIn: 230 V AC/UOut: 24 V DC
0,4
1 2 3 4 5 6 7 8 9 10
IOut [A]

Crest factor 120 V AC 230 V AC

typ. 1.55 typ. 1.78
Input current vs. output current

3,0
IIn [A]

2,5 = UIn: 230 V AC/UOut: 24 V DC
2,0
1,5
1,0
0,5

0,0
0 1 2 3 4 5 6 7 8 9 10
IOut [A]
Input connection data

Connection method Screw connection
Conductor cross section, solid 0.2 mm² ... 2.5 mm²
Conductor cross section, flexible 0.2 mm² ... 2.5 mm²
Conductor cross section flexible, with ferrule with plastic 0.25 mm² ... 2.5 mm²
sleeve
Conductor cross section flexible, with ferrule without 0.25 mm² ... 2.5 mm²
plastic sleeve
Conductor cross section AWG 24 ... 14
Stripping length 6.5 mm
Tightening torque 0.5 Nm ... 0.6 Nm
Output data
Nominal output voltage (UN) 24 V DC
Setting range of the output voltage (USet) ( constant 24 V DC ... 29.5 V DC
capacity )
Nominal output current (IN) 5A
Static Boost (IStat.Boost) 6.25 A
Dynamic Boost (IDyn.Boost) 10 A (5 s)
Selective Fuse Breaking (ISFB) 30 A (15 ms)
Magnetic circuit breaker tripping A1...A4 / B2 / C1...C2 / Z1...Z4
Control deviation Static load change 10 % ... 90 % < 0.5 %
Control deviation Dynamic load change 10 % ... 90 %, (10 < 4 %
Hz)
Control deviation change in input voltage ±10 % < 0.25 %
Short-circuit-proof yes
No-load proof yes
Residual ripple ( with nominal values ) < 30 mVPP
Connection in parallel Yes, for redundancy and increased capacity
Connection in series yes

Output data
Feedback resistance ≤ 35 V DC
Protection against surge voltage on the output ≤ 32 V DC
Rise time typical 50 ms (UOut = 10 % ... 90 %)
Output connection data

Connection method Screw connection
Conductor cross section, solid 0.2 mm² ... 2.5 mm²
sleeve
plastic sleeve
Stripping length 6.5 mm
Tightening torque 0.5 Nm ... 0.6 Nm
LED signaling
POut > 100% LED lights up yellow, output power > 120 W
POut > 75% LED lights up green, output power > 90 W
POut > 50% LED lights up green, output power > 60 W
UOut > 0.9 x USet LED lights up green
UOut < 0.9 x USet LED flashes green
Signal contact (configurable)

Signal output (configurable) Out 1
Digital 0 / 24 V DC , 20 mA
Default 24 V DC , 20 mA ( 24 V DC for UOut > 0.9 x USet )
Signal output (configurable) Out 2
Digital 0 / 24 V DC , 20 mA
Analog 4 mA ... 20 mA  5 % (Load ≤400 )
Default 24 V DC , 20 mA ( 24 V DC for POut < PN )
Relay contact (configurable) 13/14
Function N/O contact
Default closed (Uout > 0.9 USet)
Maximum contact load 24 V DC 1 A , 30 V AC/DC 0.5 A
Control input (configurable) Rem
Function Output power ON/OFF (SLEEP MODE)
Default Output power ON (>40 kΩ/24 V DC/open bridge between Rem
and SGnd)
Signal ground SGnd Reference potential for Out1, Out2, and Rem

Signal connection data

Connection method Push-in connection
Conductor cross section, solid 0.2 mm² ... 1 mm²
sleeve
plastic sleeve
Stripping length 8 mm
Reliability 230 V AC
MTBF (IEC 61709, SN 29500) > 1532000 h (25 °C)
> 930000 h (40 °C)
> 431000 h (60 °C)
Life expectancy (electrolytic capacitors) 120 V AC 230 V AC

Output current (IOut)
2.5 A > 184000 h ( 40 °C ) > 183000 h ( 40 °C )
5A > 79000 h ( 40 °C ) > 91000 h ( 40 °C )
5A > 224000 h ( 25 °C ) > 259000 h ( 25 °C )
The expected service life is based on the capacitors used. If the capacitor specification is observed, the
specified data will be ensured until the end of the stated service life. For runtimes beyond this time, error-free
operation may be reduced. The specified service life of more than 15 years is simply a comparative value.
Switching frequency Min. Max.

PFC stage 60 kHz 360 kHz
Auxiliary converter stage 90 kHz 110 kHz
Main converter stage 50 kHz 195 kHz
General data
Degree of protection IP20
Protection class I
Inflammability class in acc. with UL 94 (housing / terminal V0
blocks)
Side element version Aluminum
Hood version Stainless steel X6Cr17
Dimensions W / H / D (state of delivery) 36 mm / 130 mm / 125 mm
Dimensions W / H / D (90° turned) 122 mm / 130 mm / 39 mm
Weight 0.7 kg
Power dissipation 120 V AC 230 V AC

Maximum power dissipation in no-load condition <3W <3W
Power dissipation SLEEP MODE <3W <3W
Power loss nominal load max. < 17 W < 16 W

Efficiency 120 V AC 230 V AC

95 typ. 88.8 % typ. 89.2 %
Eta [%]

90
85
80
75 = UIn: 120 V AC/UOut: 24 V DC

70
1 2 3 4 5 6 7 8 9 10
IOut [A]
Ambient conditions
Ambient temperature (operation) -25 °C ... 70 °C (> 60 °C Derating: 2.5 %/K)
The ambient temperature (operation) refers to UL 508 surrounding air temperature.
Ambient temperature (start-up type tested) -40 °C

Ambient temperature (storage/transport) -40 °C ... 85 °C
Max. permissible relative humidity (operation) ≤ 95 % (at 25 °C, non-condensing)
Installation height ≤ 5000 m (> 2000 m, observe derating)
Vibration (operation) 5 Hz ... 100 Hz resonance search 2.3g, 90 min., resonance
frequency 2.3g, 90 min. (according to DNV GL Class C)
Shock 18 ms, 30g, in each space direction (according to IEC 60068-
2-27)
Degree of pollution 2
Climatic class 3K3 (in acc. with EN 60721)
Overvoltage category
EN 60950-1 II (≤ 5000 m)
EN 61010-1 II (≤ 5000 m)
EN 62477-1 III (≤ 2000 m)
Standards
Safety of power supply units up to 1100 V (insulation DIN EN 61558-2-16
distances)
Safety transformers for power supply units EN 61558-2-16 (air clearances and creepage distances only)
Electrical safety (of information technology equipment) IEC 60950-1/VDE 0805 (SELV)
Electrical safety (of control and regulation devices) IEC 61010-1
SELV IEC 60950-1 (SELV)
EN 60204-1 (PELV)
Limitation of mains harmonic currents EN 61000-3-2
Network version/undervoltage SEMI F47-0706; EN 61000-4-11

Standards
Rail applications EN 50121-3-2
EN 50121-4
EN 50121-5
IEC 62236-3-2
IEC 62236-4
IEC 62236-5
EMC requirements, power plant IEC 61850-3
EN 61000-6-5
HART FSK Physical Layer Test Specification Compliance Output voltage UOut compliant
Approvals
UL UL Listed UL 508
UL/C-UL Recognized UL 60950-1
UL ANSI/ISA-12.12.01 Class I, Division 2, Groups A, B, C, D
(Hazardous Location)
CSA CAN/CSA-C22.2 No. 60950-1-07
CSA-C22.2 No. 107.1-01
SIQ BG (type approved)
Shipbuilding DNV GL, PRS, BV, LR, ABS

Electromagnetic compatibility
Noise emission according to EN 61000-6-3 (residential and commercial) and EN 61000-6-4 (industrial)
CE basic standard Minimum normative Higher requirements in
requirements practice (covered)
Conducted noise emission EN 55016 EN 61000-6-4 (Class A) EN 61000-6-3 (Class B)
Noise emission EN 55016 EN 61000-6-4 (Class A) EN 61000-6-3 (Class B)
Harmonic currents EN 61000-3-2 EN 61000-3-2 (Class A) EN 61000-3-2 (Class A)
Flicker EN 61000-3-3 not required EN 61000-3-3 (Class A)
Noise emission for marine approval Minimum normative Higher requirements in

requirements of DNV GL practice of DNV GL
(covered)
DNV GL conducted noise emission Class A Class A
Area power distribution Area power distribution
DNV GL noise radiation Class A Class B
Area power distribution Bridge and deck area
Immunity according to EN 61000-6-1 (residential), EN 61000-6-2 (industrial), and EN 61000-6-5 (power station
equipment zone), IEC/EN 61850-3 (energy supply)
requirements of practice (covered)
EN 61000-6-2 (CE)
(immunity for industrial
environments)
Electrostatic discharge EN 61000-4-2
Housing contact discharge 4 kV (Test Level 2) 8 kV (Test Level 4)
Housing air discharge 8 kV (Test Level 3) 15 kV (Test Level 4)
Comments Criterion B Criterion A
Electromagnetic HF field EN 61000-4-3
Frequency range 80 MHz ... 1 GHz 80 MHz ... 1 GHz
Test field strength 10 V/m (Test Level 3) 20 V/m (Test Level 3)
Frequency range 1.4 GHz ... 2 GHz 1 GHz ... 6 GHz
Frequency range 2 GHz ... 2.7 GHz 1 GHz ... 6 GHz
Comments Criterion A Criterion A
Fast transients (burst) EN 61000-4-4
Input 2 kV (Test Level 3 - 4 kV (Test Level 4 -
asymmetrical) asymmetrical)
Output 2 kV (Test Level 3 - 4 kV (Test Level 4 -
Signal 1 kV (Test Level 3 - 4 kV (Test Level 4 -

Immunity according to EN 61000-6-1 (residential), EN 61000-6-2 (industrial), and EN 61000-6-5 (power station
equipment zone), IEC/EN 61850-3 (energy supply)
requirements of practice (covered)
EN 61000-6-2 (CE)
(immunity for industrial
environments)
Surge voltage load (surge) EN 61000-4-5
Input 1 kV (Test Level 3 - 3 kV (Test Level 4 -
symmetrical) symmetrical)
2 kV (Test Level 3 - 6 kV (Test Level 4 -
Output 0.5 kV (Test Level 2 - 1 kV (Test Level 3 -
symmetrical) symmetrical)
0.5 kV (Test Level 1 - 2 kV (Test Level 3 -
Signal 1 kV (Test Level 2 - 1 kV (Test Level 2 -
Conducted interference EN 61000-4-6
Input/Output/Signal asymmetrical asymmetrical
Frequency range 0.15 MHz ... 80 MHz 0.15 MHz ... 80 MHz
Voltage 10 V (Test Level 3) 10 V (Test Level 3)
Power frequency magnetic field EN 61000-4-8
50 Hz , 60 Hz ( 30 A/m ) 16.7 Hz , 50 Hz , 60 Hz
( 100 A/m 60 s )
not required 50 Hz , 60 Hz ( 1 kA/m , 3 s )
not required 0 Hz ( 300 A/m , DC, 60 s )
Voltage dips EN 61000-4-11
Input voltage ( 230 V AC , 50 Hz )
Voltage dip 70 % , 25 periods 70 % , 0.5 / 1 / 25 periods
( Test Level 2 ) ( Test Level 2 )
Comments Criterion C Criterion A: 0.5 / 1 / 25 periods
Voltage dip 40 % , 10 periods 40 % , 5 / 10 / 50 periods
Comments Criterion C Criterion A
Voltage dip 0 % , 1 period 0 % , 0,5 / 1 / 5 / 50 / 250
( Test Level 2 ) periods ( Test Level 2 )
Comments Criterion B Criterion A: 0.5 / 1 period
Criterion B: 5 / 50 / 250 periods

Additional basic standard EN 61000-6-5 (immunity in power station), IEC/EN 61850-3 (energy supply)
Basic standard Minimum normative Higher requirements in
requirements of EN 61000- practice (covered)
6-5
Pulse-shape magnetic field EN 61000-4-9
not required 1000 A/m
Comments none Criterion A
Damped oscillating magnetic field EN 61000-4-10
not required 100 kHz
110 A/m
not required 1 MHz
110 A/m
Attenuated sinusoidal oscillations (ring wave) EN 61000-4-12
Input not required 2 kV (Test Level 4 -
symmetrical)
not required 4 kV (Test Level 4 -
asymmetrical)
Asymmetrical conducted disturbance variables EN 61000-4-16
Input, Output, Signals 15 Hz ... 150 Hz , 10 V on 1 V 15 Hz ... 150 Hz , 30 V on 3 V
150 Hz ... 1.5 kHz , 1 V 150 Hz ... 1.5 kHz , 3 V
1.5 kHz ... 15 kHz , 1 V on 10 V 1.5 kHz ... 15 kHz , 3 V on 30 V
15 kHz ... 150 kHz , 10 V 15 kHz ... 150 kHz , 30 V
50 Hz , 60 Hz , 10 V 16.7 Hz , 50 Hz , 60 Hz , 30 V
(Permanent) (Permanent)
50 Hz , 60 Hz , 100 V 16.7 Hz , 50 Hz , 60 Hz , 300 V
(1 s) (1 s)
Attenuated oscillating wave EN 61000-4-18
Input, Output 1 MHz , 1 kV ( Test Level 3 - 100 kHz , 1 MHz , 1 kV ( Test
symmetrical ) Level 3 - symmetrical )
10 MHz , 1 kV 10 MHz , 1 kV
1 MHz , 2.5 kV 100 kHz , 1 MHz , 2.5 kV
( Test Level 3 - asymmetrical ) ( Test Level 3 - asymmetrical )
Signals 1 MHz , 1 kV 100 kHz , 1 MHz , 1 kV
( Test Level 3 - symmetrical ) ( Test Level 3 - symmetrical )
1 MHz , 2.5 kV 100 kHz , 1 MHz , 2.5 kV
( Test Level 3 - asymmetrical ) ( Test Level 3 - asymmetrical )

Key
Criterion A Normal operating behavior within the specified limits.
Criterion B Temporary impairment to operational behavior that is corrected by the device itself.
Criterion C Temporary adverse effects on the operating behavior, which the device corrects
automatically or which can be restored by actuating the operating elements.

5 Safety and installation notes The power supply is maintenance-free.

Repairs may only be carried out by the
Only qualified electricians may install, start up, and operate
manufacturer. The warranty no longer applies
the device. Observe the national safety and accident
if the housing is opened.
prevention regulations.
The specified technical characteristics relate to the factory
The power supply may only be used for its
setting of the standard device.
intended use.
Configured devices may have different technical
characteristics. The device behavior may also differ from the
documentation. The continuous total output power may not
exceed PN at 60 °C ambient temperature and
CAUTION: Before startup, observe the PStat. Boost at 40°C ambient temperature.
following Observe all the maximum output powers for
all operating conditions.
Check the device for external damage. If the
device is defective, it must not be used.
The power supply must be switched off from
outside according to EN 60950-1 (e.g., via the
line protection on the primary side).
Preferably mount the power supply in the
normal mounting position.
Ensure that the primary-side and secondary-
side wiring of the power supply are the correct
size and have sufficient fuse protection.
The power supply is a built-in device. The
IP20 degree of protection of the power supply
is intended for a clean and dry environment.
The power supply is mounted in a control
cabinet.
For the connection parameters for wiring the
power supply, such as the required stripping
length with and without ferrule, refer to the
technical data section.
As a safety measure against shock currents,
always wire the protective conductor device
terminal block to the control cabinet ground
connection.
To avoid accidental contact with live parts,
always cover the termination area
(e.g., installation in the control cabinet).
DANGER: Hazardous voltage

The power supply contains components that
have been designed for operation at
potentially lethal voltages. The accumulated
level of energy can also be high. Never carry
out work when mains voltage is present.
CAUTION: Hot surface

Depending on the ambient temperature and
load on the power supply, the housing can
become hot.

6 High-voltage test (HIPOT) 6.3 High-voltage dielectric test performed by the

customer
This protection class I power supply is subject to the Low
Apart from routine and type tests to guarantee electrical
Voltage Directive and is factory tested. During the HIPOT
safety, the end user does not have to perform another high-
test (high-voltage test), the insulation between the input
voltage test on the power supply as an individual
circuit and output circuit is tested for the prescribed electric
component. According to EN 60204-1 (Safety of machinery
strength values, for example. The test voltage in the high-
- Electrical equipment of machines) the power supply can be
voltage range is applied at the input and output terminal
disconnected during the high-voltage test and only installed
blocks of the power supply. The operating voltage used in
once the high-voltage test has been completed.
normal operation is a lot lower than the test voltage used.
High-voltage tests up to 0.8 kV AC /

1.1 kV DC can be performed as described.
For high-voltage tests > 0.8 kV AC /
1.1 kV DC, the gas-filled surge arrester must
be disconnected.
The test voltage should rise and fall in ramp
form. The relevant rise and fall time of the
ramp should be at least two seconds.
6.1 High-voltage dielectric test (dielectric strength

test)
In order to protect the user, power supplies (as electric
components with a direct connection to potentially
hazardous voltages) are subject to more stringent safety
requirements. For this reason, permanent safe electrical
isolation between the hazardous input voltage and the
touch-proof output voltage as safety extra-low voltage
(SELV) must always be ensured.
In order to ensure permanent safe isolation of the AC input
circuit and DC output circuit, high-voltage testing is
performed as part of the safety approval process (type test)
and manufacturing (routine test).
6.2 High-voltage dielectric test during the

manufacturing process
During the manufacturing process for the power supply, a
high-voltage test is performed as part of the dielectric test in
accordance with the specifications of IEC/UL/EN 60950-1.
The high-voltage test is performed with a test voltage of at
least 1.5 kV AC / 2.2 kV DC or higher. Routine
manufacturing tests are inspected regularly by a certification
body.

6.3.1 Performing high-voltage testing 6.3.2 Disconnecting the gas-filled surge arrester
If high-voltage testing of the control cabinet or the power The built-in gas-filled surge arrester inside the device
supply as a stand-alone component is planned during final ensures that the power supply is effectively protected
inspection and testing, the following features must be against asymmetrical disturbance variables (e.g., EN
observed. 61000-4-5).
– The power supply wiring must be implemented as Each surge voltage test represents a very high load for the
shown in the wiring diagram. power supply. Therefore avoid unnecessary loading or
– The maximum permissible test voltages must not be damage to the power supply due to excessive test voltages.
exceeded. If necessary, the gas-filled surge arrester inside the device
Avoid unnecessary loading or damage to the power supply can be disconnected in order to use higher test voltages.
due to excessive test voltages. Following successful completion of testing, please
reconnect the gas-filled surge arrester.
For the relevant applicable test voltages and 00

%
> 1 % P Ou
t
insulation distances, refer to the 5

> 7 0%
> 5 OK
corresponding table (see technical data: DC
electric strength of the insulation section).
M3 C
NF
QUINT POWER
1
A x8
+ +
Output DC
B
UOut
29,5V
Signal
13
14
Rem
SGnd 2
Out 1
Out 2
24V
> 100% Boost
> 75% P
> 50% Out
DC OK
HV
3 Figure 2 Disconnect gas-filled surge arrester
/=
QUINT POWER
NFC To disconnect the gas-filled surge arrester, proceed as

follows:
1. Remove power from the unit.
Input AC
5 N/- L/+ 2. Unscrew the Phillips head screw completely and keep
the gas-filled surge arrester screw in a safe place. The
4 gas-filled surge arrester is now disconnected and is no
longer functional.
Figure 1 Potential-related wiring for the high-voltage 3. Perform the surge voltage test on the power supply.
test 4. Following successful high-voltage testing, screw the
gas-filled surge arrester screw fully back into the power
Key supply.
No. Designation Color coding Potential DANGER: Risk of electric shock or

levels damage to the power supply due to using
1 DC output circuit Blue Potential 1 the wrong gas-filled surge arrester screw
2 Signal contacts Blue Potential 1 To connect the gas-filled surge arrester, only
3 High-voltage -- -- use the gas-filled surge arrester screw that
tester was originally installed in the power supply.
4 AC input circuit Red Potential 2

7 Structure of the power supply 7.2 Device dimensions
The fanless convection-cooled power supply can be 36

snapped onto all DIN rails according to EN 60715.
7.1 Function elements + +

Output
Output DC 24V
24V 5A
5A
1 Uout
UOut
2 2 Signal
65
29,5V
13
14
Signal Ground
Rem
SGnd
Out 1
+ + Out 2
Output
Output DC 24V
24V 5A
5A 24V
> 100% Boost
130
> 75% Pout
> 50% POut
9 Uout
UOut
Signal
3 DC OK DC OK
29,5V
13
QUINT POWER
14
Signal Ground
Rem
SGnd NFC
Out 1
Out 2
24V
> 100%
100% Boost
Boost
> 75% Pout
> 50% POut 4 400-500 V
Input AC 100-240 V
DC OK DC OK N/- L/+
L1/ L2 L3/+
POWER
QUINTPOWER
8 Figure 4 Device dimensions (dimensions in mm)

NFC
7
QUINT
5
131
Input AC
Input AC 100-240V
400-500 V
N/- L/+ 125
L1/ L2 L3/+ 122
2 2
6
Figure 3 Operating and indication elements
Key
No. Designation 130

80
1 DC output voltage connection terminal blocks

45
2 Accommodation for cable binders

3 Signaling connection terminal blocks
4 Status and diagnostics indicators Figure 5 Device dimensions (dimensions in mm)
5 NFC interface (Near Field Communication)
6 AC input voltage connection terminal blocks
7 Gas-filled surge arrester for surge protection (left
side of housing)
8 Universal DIN rail adapter (rear of housing)
9 Output voltage button (-) / (+)

7.3 Keep-out areas
Nominal output Spacing [mm]

capacity a b c
< 50 % 0 40 20
≥ 50 % 5 50 50
If adjacent components are active and the

nominal output power ≥ 50%, there must be
lateral spacing of 15 mm.
36
a a
b
+ +
Output
Output DC 24V
24V 5A
5A
Uout
UOut
29,5V Signal
13
14
Signal Ground
Rem
SGnd
Out 1
Out 2
24V
> 100% Boost
130
> 75% Pout

> 50% POut
DC OK DC OK
QUINT POWER
NFC
400-500 V
Input AC 100-240 V
N/- L/+
L1/ L2 L3/+
c
Figure 6 Device dimensions and minimum keep-out

areas (in mm)

7.4 Block diagram
(+) +
active +
L
PFC
-
-
N
(-) 13
OVP 14
Rem
SGnd
Out 1
Out 2
C NFC
POut
Figure 7 Block diagram
Key
Symbol Designation Symbol Designation

Surge protection (varistor, gas-filled surge Optocoupler (electrically isolating)
arrester) with filter
Bridge rectifier Additional regulatory protection against

OVP surge voltage
Inrush current limitation 13 Relay contact and signal contacts

14
Rem
SGnd
Out 1
Out 2
active
Power factor correction (PFC) Microcontroller
PFC
C
Switching transistor and main transmitter NFC interface (Near Field Communication)
NFC
(electrically isolating)
Secondary rectification and smoothing Output voltage button (-) / (+)
Filter Signal/display LEDs (POut, DC OK)

POUT
Auxiliary converter (electrically isolating)

8 Mounting/removing the power

supply
D
8.1 Mounting the power supply unit
Proceed as follows to mount the power supply:
1. In the normal mounting position the power supply is
mounted on the DIN rail from above. Make sure that the
universal DIN rail adapter is in the correct position
C
behind the DIN rail (A).
2. Then press the power supply down until the universal
DIN rail adapter audibly latches into place (B).
3. Check that the power supply is securely attached to the
DIN rail. A B
Figure 9 Removing the power supply from the DIN rail
A 8.3 Retrofitting the universal DIN rail adapter

For installation in horizontal terminal boxes it is possible to
mount the power supply at a 90° angle to the DIN rail.
No additional mounting material is required.
Use the Torx screws provided to attach the

universal DIN rail adapter to the side of the
Click power supply.
B
8.3.1 Disassembling the universal DIN rail adapter
Proceed as follows to disassemble the universal DIN rail
Figure 8 Snapping the power supply onto the DIN rail
adapter that comes pre-mounted:
8.2 Removing the power supply unit 1. Remove the screws for the universal DIN rail adapter
using a suitable screwdriver (Torx 10).
Proceed as follows to remove the power supply:
2. Separate the universal DIN rail adapter from the rear of
1. Take a suitable screwdriver and insert this into the lock the power supply.
hole on the universal DIN rail adapter (A).
2. Release the lock by lifting the screwdriver (B).
3. Carefully swivel the power supply forward (C) so that
the lock slides back into the starting position.
4. Then separate the power supply from the DIN rail (D).
8
M3x 8
M3x
Figure 10 Disassembling the universal DIN rail adapter

8.3.2 Mounting the universal DIN rail adapter 8.4.1 Mounting the UWA 182/52 universal wall
adapter
To mount the universal DIN rail adapter on the left side of the
device, proceed as follows: Proceed as follows to disassemble the universal DIN rail
1. Position the universal DIN rail adapter on the left side of adapter that comes pre-mounted:
the housing so that the mounting holes are congruent 1. Remove the screws for the universal DIN rail adapter
with the hole pattern for the mounting holes. using a suitable screwdriver (Torx 10).
2. Insert the Torx screws that were removed earlier into the 2. Separate the universal DIN rail adapter from the rear of
appropriate hole pattern on the universal DIN rail the power supply.
adapter so that the necessary drill holes on the power 3. Position the universal wall adapter in such a way that
supply can be accessed. the keyholes or oval tapers face up. The mounting
3. Screw the universal DIN rail adapter onto the power surface for the power supply is the raised section of the
supply. universal wall adapter.
4. Place the power supply on the universal wall adapter in
The maximum tightening torque of the Torx the normal mounting position (input voltage connection
screw (Torx® T10) is 0.7 Nm. terminal blocks below).
5. Insert the Torx screws into the appropriate hole pattern
on the universal wall adapter so that the necessary
mounting holes on the power supply can be accessed.
6. Screw the universal wall adapter onto the power supply.
x8 x8
M3 M3
8
M3x 8
M3x
Figure 11 Mounting the universal DIN rail adapter
8.4 Retrofitting the universal wall adapter

The UWA 182/52 universal wall adapter (Order No.
2938235) or UWA 130 universal wall adapter (Order No. Figure 12 Mounting the UWA 182/52 universal wall
2901664) is used to attach the power supply directly to the adapter
mounting surface.
The use of universal wall adapters is recommended under
The maximum tightening torque of the Torx
extreme ambient conditions, e.g., strong vibrations. Thanks
screw (Torx® T10) is 0.7 Nm.
to the tight screw connection between the power supply and
the universal wall adapter or the actual mounting surface, an
extremely high level of mechanical stability is ensured.
Make sure you use suitable mounting material
when attaching to the mounting surface.
The power supply is attached to the UWA 182
or UWA 130 universal wall adapter by means
of the Torx screws of the universal DIN rail
adapter.

8.4.2 Mounting the UWA 130 2-piece universal wall 8.5 Fix connection wiring to the power supply
adapter
Two receptacles for the bundled attachment of the
Proceed as follows to disassemble the universal DIN rail connection wiring are integrated in the left and right housing
adapter that comes pre-mounted: panel. Use cable binders to secure the connection wiring
1. Remove the screws for the universal DIN rail adapter (optional PKB 140X3,6 - Order No. 1005460).
using a suitable screwdriver (Torx 10). Proceed as follows to secure the connection wiring:
2. Separate the universal DIN rail adapter from the rear of – Wire the power supply with sufficient connection
the power supply. reserve (input terminal blocks, output terminal blocks,
3. Position the universal wall adapter. The mounting signal terminal blocks)
surface for the power supply is the raised section of the – Bundle and set up the connection wiring so that the
universal wall adapter. cooling grilles on the top and bottom of the housing are
4. Place the power supply on the universal wall adapter in covered as little as possible.
the normal mounting position (input voltage connection – Thread the cable binders into the necessary
terminal blocks below). receptacles for the cable binders.
5. Insert the Torx screws into the appropriate hole pattern
on the universal wall adapter so that the necessary
mounting holes in the side flanges of the power supply
can be accessed.
6. Screw the two-piece universal wall adapter onto the
power supply.
U
Out
Sig
13 na
l
14
Re
m
SG
nd
Ou
t1
Ou
8 t2
M3x
M3x
8 >1
> 700%
> 55% Boo
DC0% P st
OK out
Figure 14 Lay and align connection wiring
– Secure the connection wiring with the cable binders.

Make sure that the connection wiring is attached safely
and securely without damaging the connection wiring.
Figure 13 Mounting the UWA 130 universal wall adapter
U
Out
Sig
13 na
l
14
Re
m
SG
nd
Ou
t1
Ou
t2
>1
> 700%
> 55% Boo
DC0% P st
OK out
Figure 15 Secure connection wiring with cable binder

– Shorten the excess length of the cable binder ends. 9 Device connection terminal blocks
– Then check again that the connection wiring is properly
secured. The AC input and DC output terminal blocks on the front of
the power supply feature screw connection technology. The
signal level is wired without tools by means of Push-in
connection technology.
For the necessary connection parameters for

the connection terminal blocks, refer to the
technical data section.
9.1 Input
U
Out
Sig
13
14
Re
na
l The power supply is operated on single-phase AC systems
m
SG
Ou
Ou
nd
t1
t2
or two outer conductors of three-phase systems. The power
>1
> 700%
> 55% Boo
DC0% P st
supply is connected on the primary side via the INPUT L/N/
OK out
 connection terminal blocks.
Figure 16 Shorten protruding ends of the cable binder
The power supply is approved for connection
to TN, TT, and IT power grids with a maximum
NOTE: Mechanical damage to the connection phase-to-phase voltage of 240 V AC.
wiring caused by friction
In extreme ambient conditions, e.g., strong
vibrations, protect the connection wiring TN-S TN-C
L L
against mechanical damage using additional N PEN
insulation material. The additional insulation PE
material for protecting the connection wiring is
limited to the area where the cable binders are
attached. N L N L
+ − + −
L1 L1
L2 L2
L3 L3
N PEN
PE
N L N L
+ − + −
TT iT
L L
PEN N
N L N L
+ − + −
L1 L1
L2 L2
L3 L3
N
N L N L
+ − + −
Figure 17 Network types

9.2 Protection of the primary side 9.3 Output

Installation of the device must correspond to EN 60950-1 By default, the power supply is pre-set to a nominal output
regulations. It must be possible to switch off the device using voltage of 24 V DC.
a suitable disconnecting device outside the power supply. The output voltage is adjusted via the two arrow keys (-)
The line protection on the primary side is suitable for this and (+) on the front of the power supply.
(see technical data section).
When you press the arrow key once briefly, the output
voltage is reduced (-) or increased (+) by 3 mV. When you
DANGER: Hazardous voltage press the arrow key for longer, the voltage is adjusted in
An all-pos. fuse must be present for operation 100 mV increments.
on two outer conductors of a three-phase
system. 9.4 Protection of the secondary side
The power supply is electronically short-circuit-proof and
Protection for AC supply no-load-proof. In the event of an error, the output voltage is
limited
Input AC 100...240 V
L L If sufficiently long connecting cables are used,
N fuse protection does not have to be provided
PE
for each individual load.
If each load is protected separately with its
own protective device, the selective shutdown
in the event of a fault enables the system to
remain operational.
N N/- L/+
PE
Figure 18 Pin assignment for AC supply voltage
Protection for DC supply
Input DC 110...250 V
+ +
-
PE
N/- L/+
Figure 19 Pin assignment for DC supply voltage
DC applications require upstream installation of a fuse that

is permitted for the operating voltage.

10 Output characteristic curves

This section describes the various output characteristic curves together with their areas of application for customization to
your specific application. The U/I Advanced characteristic curve is set by default.
+ -
M
Keeps temperatures
Loads with high inrush Selective tripping of
Application Normal load System extension
current
Energy storage charging
fuses
low in the event of Short circuit, non-fused
faults
A stable 24 V, even in the No over-dimensioned

Parallel loads continue Low thermal stress in Enables configuration
Your benefits Reliable power supply event of a sustained power supply unit Fast charging
working the even of faults without fuse
overload required
Characteristics
U/I Advanced -
Smart HICCUP - -
FUSE MODE - - -
Symbol Designation
Suitable for the application
- Not suitable for the application

10.1 U/I Advanced output characteristic curve 10.2 Smart HICCUP output characteristic curve
The preset U/I Advanced output characteristic curve is The SMART HICCUP output characteristic curve keeps the
optimized for the following applications: thermal load of the connecting cables at a low level in the
– For selective tripping of standard circuit breakers (SFB event of a sustained overload. If loads are not protected or
technology). The power supply supplies up to 6 times are protected in a way that is not permitted, the loads are
the nominal current for 15 ms. Loads connected in supplied for 2 s. The DC output of the power supply is then
parallel continue working. switched off for 8 s. This procedure is repeated until the
– When supplying loads with high switch-on currents, cause of the overload has been remedied.
such as motors. The dynamic boost of the power supply The preset Smart HICCUP output characteristic curve is
supplies up to 200% of the nominal power for 5 s. This optimized for the following applications:
ensures that sufficient reserve energy is available; – If only a low short-circuit current is permitted.
overdimensioning of the power supply is not necessary. – If following an overload or short circuit the output
– For system extension. With the static boost, up to voltage should be made available again automatically.
125% of the nominal output power is available for a
sustained period (up to 40°C).
UOut [V]
UN
– For fast energy storage charging (e.g., of batteries) to 5s
supply a wide range of loads. The power supply
operates in the nominal operating range. Energy supply UN
to the load is ensured. 2
UOut [V]
UN
5s
0 IN IStat. Boost
100% 125% 200%
UN
3
IOut [A]
0 IN IStat. Boost
100% 125% 200% IDyn. Boost 2s
IOut [A]
0
5s t [s]
IDyn. Boost
Figure 21 Smart HICCUP output characteristic curve
0
t [s]
Figure 20 U/I Advanced output characteristic curve

10.3 FUSE MODE output characteristic curve

In the event of an overload (e.g., short circuit), the power
supply switches off the DC output permanently. The value of
the switch-off threshold and the time period for which it may
be exceeded can be freely selected. The power supply is
restarted via the remote contact. As an option, the power
supply can be switched on by switching the supply voltage
on the primary side off and on.
Selecting the FUSE MODE output characteristic curve sets
the following default values.
– tFuse = 100 ms
– IFuse = IN
IOut [A]
IFuse
0
tFuse
t [s]
Figure 22 FUSE MODE output characteristic curve

11 Configuring the power supply 11.2 Configuring the power supply

To configure the power supply, proceed as follows:
With the fourth generation of the QUINT POWER power
supply, it is now possible for the first time to adapt the – Before you can configure the power supply, it should
behavior of the power supply. In addition to setting the either be disconnected from the supply voltage or
output voltage and selecting the output characteristic switched to SLEEP MODE.
curves, you can configure signal outputs Out 1, Out 2, and – To switch the power supply to SLEEP MODE, use one
floating signal contact 13/14, for example. Configuration of of the external circuits. The following connection
the remote input for controlling the power supply or versions are possible between the Rem (remote input)
specification of signal options and signal thresholds also and SGnd (signal ground) connection terminal blocks.
extend the range of possible applications.
The power supply is configured via the device's internal NFC Signal a) < 15 k
(near field communication) interface.
13
14
The power supply behaves like a passive Rem
NFC tag. An auxiliary power source is
SGnd
required in order to supply the power supply
Out 1 b)
with configuration data.
Out 2
11.1 Configuration with PC software

Figure 23 SLEEP MODE connection versions
In order to configure the power supply via the NFC interface,
the following hardware and software requirements must be – Hold the USB-PROG-ADAPTER in front of the mounted
met: power supply so that the NFC antenna symbols are
– PC or notebook (as of Windows 7, Microsoft.Net congruent with one another.
Framework 4.5, USB 2.0 interface, 50 MB hard disk
capacity, QUINT POWER software).
– Programming adapter:
TWN4 MIFARE NFC USB ADAPTER (Order No.
2909681) is plugged into the USB interface.
– Programming software: the QUINT POWER software
has been successfully installed.
l
na
Sig
t
UOu
13
14
Rem
nd
SG 1
Out 2
t
os
Out
Bo
% ut
00 o
> 15% P
> 70%
> 5 OK
DC
M3
x8 C
QUINT POWER
NF
NFC
DAT
CONN
Figure 24 Configuration of the power supply
– In the programming interface of the QUINT POWER

software, press the [Read] button. The current device
and configuration data for the power supply is read and
displayed.
If a connection cannot be established

between the USB-PROG-ADAPTER and the
power supply, more detailed information can
be found in the user manual for the QUINT
POWER software.

For information regarding the configuration of 12 Boost currents

the power supply, such as selecting the
The power supply provides the static boost (IStat. Boost) for a
characteristic curve and output parameters,
sustained load supply or the time-limited dynamic boost
refer to the user manual for the QUINT
(IDyn. Boost).
POWER software.
12.1 Static Boost
11.3 Configuration with NFC-capable mobile For system expansion purposes, the sustained static boost
terminal device (IStat. Boost) supports the load supply with up to 125 % of the
The QUINT POWER app enables you to conveniently nominal current of the power supply. The static boost is
configure the power supply using a mobile terminal device, available at an ambient temperature of up to 40 °C.
such as a smartphone.
POut [W]
In order to configure the power supply via the NFC interface, PDyn. Boost 200%
the following hardware and software requirements must be
met:
PStat. Boost 125%
– NFC-capable mobile terminal device with Android PN 100%
operating system as of Version 4.1.x (Jelly Bean) 75%
– QUINT POWER app (Google Play Store)
For information regarding the configuration of -25 40 60 70

the power supply, such as selecting the TA [°C]
characteristic curve and output parameters,
please refer to the QUINT POWER app. Figure 25 Performance characteristic in static boost
12.2 Dynamic Boost

11.4 Ordering a configured power supply
Dynamic boost (IDyn. Boost) delivers up to 200 % of the power
Customer-specified QUINT POWER power supplies are supply nominal current to supply high loads. This temporary
ordered as a KMAT item (configurable material) and are power supply to the load lasts a maximum of 5 s at an
configured during the production process in the factory. The ambient temperature of up to 60 °C. The energy supplied
power supply is therefore supplied ready to connect for your adaptively for the load supply and the recovery time (tPause)
specific application. are calculated based on the specific load situation using
algorithms (see recovery time tables).
You can type in the the web code
IOut [A]
phoenixcontact.net/webcode/#0852
to configure and order your power supply.
tDyn.Boost tDyn.Boost
IDyn.Boost
tPause
IBase Load
t [s]
Figure 26 Basic curve of the dynamic boost process

Use the following tables to determine the required recovery 12.2.3 Example: Determining the recovery time
time (tPause) at the maximum dynamic boost current (IDyn. (tPause)
Boost) based on the following values: At an output current (IBase Load) of 2 A, the dynamic output
– IBase Load current (IDyn. Boost) of 10 A increases for 2 s (tDyn. Boost).
– Duration of the boost current (tDyn. Boost) After a recovery time (tPause) of 2.3 s, the dynamic boost is
– Ambient temperature (40 °C or 60 °C) available once again.
If a current that is lower than the maximum IBase Load IDyn. Boost tDyn. Boost [s]
available dynamic boost current (IDyn. Boost) is
[A] [A] 1 2 3 4 5
required for the same period, the recovery
time may (tPause) decrease. 0 10 1 2 3,1 4,1 6
1 10 1,1 2,1 3,2 4,2 6

12.2.1 Recovery times at an ambient temperature of
40 °C 2 10 1,1 2,3 3,4 4,5 6
tPause [s]
3 10 1,3 2,6 3,8 6 7
IBase Load IDyn. Boost tDyn. Boost [s] 4 10 1,7 3,4 5 7 9

[A] [A] 1 2 3 4 5 5 10 2,9 6 9 12 15
0 10 1 2 3,1 4,1 6
6,25 10 36 71 106 141 176
1 10 1,1 2,1 3,2 4,2 6
2 10 1,1 2,3 3,4 4,5 6 Figure 29 Example recovery time for ≤ 40°C
tPause [s]
3 10 1,3 2,6 3,8 6 7
4 10 1,7 3,4 5 7 9
5 10 2,9 6 9 12 15
6,25 10 36 71 106 141 176
Figure 27 Required recovery times at ≤ 40°C
12.2.2 Recovery times at an ambient temperature of

60 °C
IBase Load IDyn. Boost tDyn. Boost [s]

[A] [A] 1 2 3 4 5
0 10 2,9 6 9 12 15
1 10 2,9 6 9 12 15
tPause [s]
2 10 3,3 7 10 14 17
3 10 4,1 9 13 17 21
4 10 7 14 20 27 33
5 10 32 63 94 125 157
Figure 28 Required recovery times at ≤ 60°C

13 SFB technology 13.3 SFB configuration

Observe the following framework conditions for determining
SFB Technology (selective fuse breaking) can be used to
the maximum distance between the power supply and load:
quickly and reliably trip miniature circuit breakers and fuses
connected on the secondary side. In the event of a short – The performance class of the power supply
circuit on the secondary side, the power supply supplies up – The cross section of the connecting cable
to 6 times the nominal current for 15 ms. The faulty current – The tripping characteristic of the fuse component
path is switched off selectively.
Loads that are connected in parallel are still supplied with
energy. Operation of these system parts is ensured. In order + +
to always enable the reliable tripping of circuit breakers and Power supply unit Load
- -
fuses, certain framework conditions must be observed (see
SFB configuration section). l
The U/I Advanced output characteristic curve Figure 31 Schematic diagram of the maximum cable
supports SFB technology. length
13.1 Tripping circuit breakers

The circuit breaker is tripped by the high SFB current of the
power supply, typically within 3 to 5 ms. As a result, voltage
dips at loads that are connected in parallel are avoided.
I [A]
6x IN
typ. 3 - 5 ms
IN
0
t [s]
Figure 30 SFB pulse trips circuit breakers
13.2 Tripping a fuse

Fuses are tripped by melting the predetermined breaking
point inside the fuse capsule. The tripping characteristic of
the fuse is described by the melting integral (I²t). A high
current is crucial in order to achieve a very short tripping
time.

13.4 Maximum distance between the power supply and load

The distances given in the table are worst-case values and therefore cover the entire tolerance range for the magnetic tripping
of circuit breakers. The possible distances are often greater in practice.
13.4.1 Thermomagnetic device circuit breaker, type: Phoenix Contact CB TM1 SFB
Maximum distance l [m] with device circuit breaker Conductor cross section
A [mm²] 0.75 1.0 1.5 2.5
AWG 18 (17) 16 14
Phoenix Contact CB TM1 1A SFB P 27 36 54 91
CB TM1 2A SFB P 10 13 20 34
The cable lengths determined are based on the following parameters:
Tripping: magnetic
DC correction factor (0 Hz): Phoenix Contact = 1,0
Characteristics: C
Characteristic C (10 times the rated current) x correction factor
Ambient temperature: +20 °C
Internal resistance Ri of the device circuit taken into consideration
breaker:
Comments: In addition to the short-circuit current, the power supply unit also supplies
half the nominal current for load paths connected in parallel.

13.4.2 Thermomagnetic circuit breaker, type: Siemens 5SY, ABB S200
Maximum distance l [m] with circuit breaker Conductor cross section

A [mm²] 0.75 1.0 1.5 2.5
AWG 18 (17) 16 14
Siemens 5SY A1 78 105 157 263
A1.6 58 77 116 194
A2 49 65 98 164
A3 35 47 70 118
A4 20 27 40 68
B2 24 33 49 82
C1 7 9 14 24
C1.6 3 5 7 13
C2 3 4 6 10
ABB S200 C2 1 1 2 4
Z1 64 85 128 214
Z1.6 46 62 93 156
C2 42 57 85 143
C3 30 41 61 102
C4 17 23 34 57
Tripping: magnetic
DC correction factor (0 Hz): Siemens = 1.4; ABB = 1.5
Characteristics: A, B, C, Z
Characteristic A (3 times the rated current) x correction factor
Characteristic B (5 times the rated current) x correction factor
Characteristic C (10 times the rated current) x correction factor
Characteristic Z (3 times the rated current) x correction factor
Internal resistance Ri of the device circuit taken into consideration
breaker:

13.4.3 Fuse, type: Cooper Bussmann GMA xA, GMC xA
Maximum distance l [m] with fuse Melting integral I²t Conductor cross section
[A²s]
A [mm²] 0.75 1.0 1.5 2.5
AWG 18 (17) 16 14
Cooper Bussmann GMA 1A 0.48 48 64 97 162
GMA 1.25A 0.84 36 48 72 120
GMA 1.5A 1.6 19 25 38 64
GMA 1.6A 2 15 20 31 51
GMA 2A 3.1 9 13 19 33
GMC 1A 1.8 15 20 31 52
GMC 1.25A 3.4 8 11 16 27
Tripping: thermal
Characteristics: Cooper Bussmann GMA (fast-blow - fast acting)
Cooper Bussmann GMC (medium-blow - medium time delay)
Internal resistance Ri of the fuse: taken into consideration

14 Signaling 14.1 Location and function of the signaling elements
A floating signal contact and two digital outputs are available

for preventive function monitoring of the power supply. UOut
29,5V Signal 1
Depending on the configuration of the power supply, either
the two digital outputs or one digital and one analog output 13
can be selected. The signal outputs are electrically isolated 14
from the input and output of the power supply.
Rem
The current device status of the power supply is signaled 2
9 SGnd
using four LED status indicators. The function of each LED
status indicator is assigned to a fixed event. Out 1 3
In addition, the power supply can be switched off and on via 8 Out 2
24V
an external circuit. 4
The signal outputs are configured on the software side using > 100% Boost
7
the QUINT POWER software or the QUINT POWER app. > 75%
Upon delivery, the power supply is pre-allocated a default > 50% POut 5
configuration for the signal outputs. 6 DC OK
Figure 32 Position of signaling elements
Key
No. Signaling elements

1 13/14 floating switch contact (N/O contact)
2 Rem, remote input (switch power supply off and on)
3 SGnd, signal ground (reference potential for signals
Out 1, Out 2)
4 Out 1 (digital output, function depends on the signal
option set)
5 Out 2 (digital or analog output, function depends on
the signal option set)
6 LED status indicator DC-OK
LED on: UOut > 90% x USet
LED flashing: UOut < 90 % x USet
7 LED status indicator POut >50 % (output power
>60 W)
8 LED status indicator POut >75 % (output power
>90 W)
9 LED status indicator POut >100 %, boost mode
(output power >120 W)

14.1.1 Floating signal contact 14.1.3 Active analog signal output

In the default configuration, the floating switch contact The signal output "Out 2" can be used as an analog signal
opens to indicate that the set output voltage has been output to continuously monitor the device workload.
undershot by more than 10 % (UOut < 0.9 x UN). Signals and The 4 ... 20 mA signal is applied between the connection
ohmic loads can be switched. For heavily inductive loads terminal blocks "Out 2" and "SGnd". It is proportional to the
(e. g. a relay), a suitable protective circuit (e. g. a set signaling parameter.
freewheeling diode) is necessary.
Signal
Signal max. 30 V AC 500mA PLC
24 V DC 1A PLC 13 Analog Input
13 Digital Input
14
14 DI x
Rem
Rem SGnd GND
SGnd GND Out 1
Out 1 Out 2 AI x 4...20 mA
Out 2
Figure 35 Signaling
Figure 33 Signaling
14.1.2 Active signal outputs, digital

Signals are forwarded to the higher-level controller via the
"Out 1" and "Out 2" signal outputs.
The 24 V DC signal is applied between the connection
terminal blocks "Out 1" and "SGnd" or between "OUT 2" and
"SGnd". It can carry a maximum of 20 mA.
By switching from "Active High" to "Active Low", the signal
output "Out 1" indicates that the set output voltage has been
undershot by more than 10 % (UOUT < 0.9 x UN).
In the default configuration, the signal output "Out 2"
indicates that the nominal power has been exceeded. The
power supply then switches to boost mode. Thanks to this
preventive function monitoring, critical operating states can
be recognized at an early stage, prior to a voltage dip
occurring.
Signal
PLC
13 Digital Input
14
Rem
SGnd GND
Out 1 DI x 0/24 V DC
Figure 34 Signaling

14.2 Preventive function monitoring

In contrast to the default signaling set upon delivery, you can customize this to the specific needs of the system. The following
signal options can be selected to signal system states.
QUINT POWER default settings upon delivery Out 1 Out 2 Relay 13/14 Out 2
digital digital floating analog
0/24 V DC 0/24 V DC 24 V DC / ≤ 1 A 4 ... 20 mA
20 mA 20 mA 30 V AC / ≤ 0.5 A
Output voltage ① 25 ... 135 % Default  Default ① 0 ... 32 V DC
V ② 90 % ② 0 ... 30 V DC
Output current ① 5 ... 200 %    ① 0 ... 10 A

A ② 100 % ② 0 ... 5 A
Output power ① 5 ... 200 %  Default  ① 0 ... 240 W

P ② 100 % ② 0 ... 120 W
Operating hours ① 0 ...  h    --

0 0 0 h ② 10 years
Early warning of Warning of    --

high temperature derating
Voltage limitation Surge voltage at    --

OVP active output
Input voltage OK 10 ms after mains  --  --

ACOK failure
Key
Symbol Description
① Setting range
② Default setting of the standard item
Default Configuration set upon delivery
 Configuration that can be selected
-- Configuration that cannot be selected
The simultaneous control of multiple signal outputs by means of one signal option is possible, as is the use of logic operations
to link multiple signal options to one control. The power supply is configured using the QUINT POWER software or the QUINT
POWER app.

14.3 Description of signaling is true if a control cabinet fan or cooling system fails. In the
event of any form of overtemperature, the power supply
14.3.1 Output voltage provides a warning by means of this signal, well before the
Signals whether the output voltage is in the preset range. If supply of the loads is in any danger.
the output voltage of the power supply falls below the set Specifications regarding the available output power (see
threshold value, the signal state changes. derating section).
Example of use 14.3.6 Voltage limitation active

Indicates whether the connected load is being supplied. If the circuit inside the device for protecting against surge
Used to quickly detect a load circuit that is not being voltages is activated at the output, the signal state changes.
supplied (e.g., in the event of mains failure or short circuit in
the supply line). Example of use
Normative requirements stipulate that an upper voltage limit
14.3.2 Output current must be observed at the output in the event of an error. It
If the output current of the power supply exceeds the set must therefore be ensured, for example, that safety-related
threshold value, the signal state changes. controllers are not supplied with an output voltage that
exceeds 32 V DC, even in the event of an error. If foreign
Example of use bodies (ferrules, screws, etc.) enter the power supply and
generate an error, the signal state changes.
In the case of system extensions, loads are added. This
increases the utilization of the power supply. Preventive
14.3.7 Input voltage OK
function monitoring detects critical operating states in good
time. Action can be taken before system downtime occurs. The power supply signals a mains failure at least 10 ms
before shutting off.
14.3.3 Output power
Example of use
If the output power of the power supply exceeds the set
threshold value, the signal state changes. In the event of a mains failure, the power supply continues to
supply the load with nominal power for at least 20 ms.
Example of use Failure of the input voltage is signaled 10 ms before the
output voltage falls, which means that this information is
In the case of system extensions, loads are added. This
provided to the higher-level controller at an early stage.
increases the utilization of the power supply. Preventive
System states can therefore be stored promptly without any
function monitoring detects critical operating states in good
loss of data as a result of the unexpected failure of the
time. Action can be taken before system downtime occurs.
supply voltage.
14.3.4 Operating hours
If the preset operating time of the power supply is exceeded,
the signal state changes.
Example of use
For systems with a very long operating time, such as wind
turbine generators or refineries, maintenance intervals are
planned. You can even schedule the maintenance date
during configuration based on the ambient temperature and
utilization of the power supply.
14.3.5 Early warning of high temperature

Before the power supply protects itself through power
derating in the event of an overtemperature, the signal state
changes.
Example of use
Outdoor control cabinets can reach a high internal
temperature depending on the position of the sun. The same

14.4 Remote input When using a PLC output, select the following external
circuit version to switch the power supply to SLEEP MODE.
The power supply is switched on and off using the digital
remote input of the power supply. When switched off, power
transmission is deactivated on the DC output side of the Signal a)
PLC
PNP output
power supply. The load connected to the DC output terminal 13 < 1 k
Gnd
blocks is no longer supplied with energy. The operating 14
mode where the DC output side is deactivated is called
Rem
SLEEP MODE.
SGnd
To switch the power supply to SLEEP MODE, select one of Out 1 PLC
the external circuit versions below. The external circuit is b)
Out 2 NPN output
wired between signal terminal blocks Rem (remote input) Gnd
and SGnd (signal ground).
Figure 38 External wiring versions with PNP and NPN
Signal a) < 15 k output
13
14.5 LED status indicators
14
Rem Four LED status indicators are integrated in the front of the
SGnd power supply, which indicate the current device state.
Out 1 b) The green DC OK LED indicates the current status of the
Out 2 output voltage (UOut). The DC OK LED is permanently on as
long as the value of the output voltage UOut is ≥ 0.9 x USet. If
the value of the output voltage is < 0.9 x USet, the green
Figure 36 External wiring versions, enable DC OK LED flashes.
SLEEP MODE Depending on the required output power of the connected
load, the three POut LEDs, which indicate the current output
To switch the power supply back on, select one of the power, light up. Assuming that the provided output power is
following external circuits between signal terminal blocks > 50% of the nominal output power, the > 50% LED lights
Rem and SGnd. Power transmission inside the device is up green. If the demanded power continues to increase until
activated again. As usual, the energy for supplying the loads it is above 75%, the > 75% LED lights up green in addition
is available at the DC output terminal blocks. to the > 50% LED. If the required output power is then
greater than the nominal device power, the power supply
Signal a) < 40 k operates in boost mode. In boost mode, the > 100% LED
13 additionally lights up yellow.
14
Rem
SGnd
Out 1 b)
Out 2
Figure 37 External wiring versions, disable

SLEEP MODE

14.6 U/I Advanced characteristic curve signaling

The following table shows the standard assignment for signaling for the U/I Advanced characteristic curves which is set by
default.
Normal operation BOOST Overload operation

POut < PN POut > PN UOut < 0.9 x USet
LED: POut >100 % yellow
Signal Out 2: POut < PN Default Active High Active Low Active Low
LED: POut > 75 %
LED: POut > 50 % green
LED: DC OK
Relay: 13/14, DC OK closed closed open

Default
Signal Out 1: DC OK Active High Active High Active Low
LED off LED on LED flashing
Figure 39 Signal image for U/I Advanced
14.7 SMART HICCUP characteristic curve signaling

The following table shows the standard assignment for signaling for the SMART HICCUP characteristic curve.
Normal operation BOOST Overload operation

POut < PN POut > PN UOut < 0.9 x USet
LED: POut >100 % Yellow
LED: POut > 75 %
LED: POut > 50 % Green
LED: DC OK
Relay: 13/14, DC OK Closed Closed Open

Default
Figure 40 Signal image for SMART HICCUP

14.8 FUSE MODE characteristic curve signaling

The following table shows the standard assignment for signaling for the FUSE MODE characteristic curve.
Normal operation BOOST FUSE MODE

POut < PN POut > PN I > IFuse for t > tFuse
LED: POut >100 % Yellow
LED: POut > 75 %
LED: POut > 50 % Green
LED: DC OK
Relay: 13/14, DC OK Closed Closed Open

Default
Figure 41 Signal image for FUSE MODE
14.9 SLEEP MODE signaling

In SLEEP MODE, all LEDs are off, all signals are low, and the relay switching contact is open.

14.10 Special immunity for the signal level
14.10.1 Surge protection for the high-voltage area at the power plant
Surge protection (Phoenix Contact Order No.: 2905223 or comparable protection) must be implemented for power plant
applications when using signal connection types t (telecommunications area), h (high voltage area) or f (field) in accordance
with IEC/EN 61850-3 or signal connection types 3 (process area) and 4 (high voltage area) in accordance with EN 61000-6-5.
When using the digital signals, a relay (Phoenix Contact Order No.: 2900299 or a comparable relay) can be implemented.
14.10.2 Surge protection for signals in railway applications

Surge protection (Phoenix Contact Order No.: 2905223 or comparable protection) must be implemented for railway
applications when using signals in accordance with EN 62236-4 and EN 50121-4.
14.10.3 Surge protection for devices in use in safety-related systems

Surge protection (Phoenix Contact Order No.: 2905223 or comparable protection) must be implemented for railway
applications when using signals in accordance with EN 61000-6-7 for devices provided to perform functions in safety-related
systems (functional safety) in industrial settings.
Uout
Signal
13
PLC
14
Rem Digital Input
Sgnd
5 6
Out 2
1 2
> 100% Boost GND
> 75% 3 4
> 50% POut
DC OK
Figure 42 Schematic diagram, signal wiring with TRABTECH surge protection
Uout
Signal
13
PLC
14
Rem 11/13(+)
Digital Input
A2-
Sgnd DI x 0/24 V DC
Out 1
Out 2
A2 11
> 100% Boost A1+ 14
A1 14 GND
> 75%
> 50% POut 12
DC OK
Figure 43 Schematic diagram, signal wiring with relay module

15 Operating modes 15.2 Parallel operation

You can connect several power supplies in parallel in order
15.1 Series operation to increase the power or to supply the loads redundantly.
To double the output voltage, connect two power supplies in
series. Only use power supplies with the same performance IN IN
class and configuration for series operation. If two 24 V DC + − + −
power supplies are connected in series, an output voltage of
48 V DC is available to supply the loads.
+
+ + + −
- - +24 V -
Σ = IN
+48 V -48 V + −
Figure 45 Schematic diagram in parallel operation

+ + -24 V +
Observe the following points when carrying out parallel
- - - connection:
1. Use power supplies of the same type and performance
Figure 44 Schematic diagrams in series operation class
2. Setting the same output voltages
3. Using the same cable cross sections for wiring
4. Using the same cable lengths for the DC convergence
point
5. Operating power supplies in the same temperature
environment
6. When three or more power supplies are connected in
parallel, each output must be protected (e.g., with
circuit breakers, fuses or decoupling modules)
We recommend the configuration "parallel

operation" for a parallel connection.
For more detailed information on the
operating mode for parallel operation, refer to
the user manual for the QUINT POWER
software or the QUINT POWER app.

15.2.1 Redundancy operation Certain specifications apply in redundancy operation with

regard to the configuration of the keepout areas. In
Redundant circuits are suitable for supplying systems and
redundancy operation, the power supplies are operated with
system parts which place particularly high demands on
maximum half the nominal power. The keepout areas are
operational reliability.
therefore reduced.
If energy is to be supplied to the load with 1+1 redundancy,
Using the signaling settings, you can monitor whether both
two power supplies of the same type and performance class
power supplies are being operated with ≤ half the nominal
must be used. In the event of an error, it must be ensured
load. In the case of system extension, an overload is
that one of the power supplies is able to provide the total
prevented if one of the power supplies fails.
required power for the load. This means that in redundancy
mode, two 5 A power supplies supply a load with a nominal
15.2.2 Increased power
current of 5 A, for example. During normal operation of the
power supplies, each power supply therefore supplies When n power supplies are connected in parallel, the output
2.5 A. current is increased to n x IN. Parallel connection for
Always use cables with the same cross sections and lengths increased power is used when extending existing systems.
when wiring the power supplies on the DC output side. If the individual power supply does not cover the current
consumption of the most powerful load, parallel connection
Redundancy modules can be used to 100% decouple two of power supplies is recommended.
power supplies from one another and to ensure the supply.
A distinction is made here between passive and active
redundancy modules. Optimum decoupling with When three or more power supplies are
simultaneous monitoring and minimal power dissipation can connected in parallel, each output must be
be achieved with the QUINT ORING or QUINT S-ORING protected separately, e.g., by a circuit
active redundancy module. breaker, fuse or decoupling module such as
QUINT ORING, QUINT S-ORING or
QUINT DIODE.
IN IN
+ − + −
IN IN
+ – + –
+
−
+
–
+ −
Σ = IN
Figure 46 Schematic diagram, redundant operation with IΣ= 2 x IN

QUINT ORING + –
Figure 48 Schematic diagram of increased performance

IN IN
+ − + −
+
−
Σ = IN
Figure 47 Schematic diagram, redundant operation with
QUINT S-ORING

16 Derating 16.3 Installation height

The power supply can be operated at an installation height
The QUINT POWER power supply runs in nominal
of up to 2000 m without any limitations. Different data
operation without any limitations. For operation outside the
applies for installation locations above 2000 m due to the
nominal range, the following points should be observed
differing air pressure and the reduced convection cooling
depending on the type of use.
associated with this (see technical data section). The data
16.1 Ambient temperature provided is based on the results of pressure chamber testing
performed by an accredited test laboratory.
When operating the power supply at an ambient
225
POut [%]
temperature of > 60 °C, a power derating of 2.5 %/K should
be observed. Up to an ambient temperature of 40 °C, the
200
175
power supply can take power from the static boost for a
sustained period. In the 40 °C to 60 °C temperature range,
150

125
the power supply can output more than the nominal power 100
for a sustained period. 75
50 = PN 100 % 60 °C
= PStat. 125 % 40 °C
POut [W]
25
PDyn. Boost = PDyn. 200 % 60 °C
200% 0
0 1000 2000 3000 4000 5000
PStat. Boost H [m]

125%
PN 100% Figure 50 Output power depending on the installation
75%
height
-25 40 60 70
TA [°C]
Figure 49 Output power depending on the ambient

temperature
16.2 Input voltage
Derating 1 %/V
UIn TA IOut UOut
< 100 V AC
≤ 60 °C IN
< 110 V DC
24 V DC
< 115 V AC
≤ 40 °C IStat. Boost
< 110 V DC

16.4 Position-dependent derating

The fanless convection-cooled power supply can be snapped onto all DIN rails according to EN 60715.
The power supply should be mounted horizontally for heat dissipation reasons (AC connection terminal blocks
facing downward). Please observe the derating for any mounting other than the normal mounting position.
Reduce the output power based on the prevailing ambient temperature.
The recommended output power for different mounting positions and ambient temperatures can be found in the
characteristic curves below.
Exceeding these values will reduce the service life of the power supply.
16.4.1 Normal mounting position
225
POut [%] 200
175
150
125
U
29Out
,5V
13
Sig
na
100

l
14
Re
SG
m
nd 75
= PN 100 %
Ou
24 t1
V Ou
50
t2
>1
> 00%
> 575% Boo
DC0% P st = PStat. 125 %
OK out
25
= PDyn. 200 %
0
QUINT POWER
NF
C
-25 0 10 20 30 40 50 60 70
Y
T [°C]
Z
16.4.2 Rotated mounting position 90° Z-axis
225
POut [%]
200
175
150
125
100
75
= PN 100 %

50
Signal
= PStat. 125 %
25
= PDyn. 200 %
> 100% Boost
13
14
Rem
> 50% Pout

SGnd
29,5V
UOut
Out 1
0
Out 2
> 75%
DC OK
-25 0 10 20 30 40 50 60 70
24V
NFC
Y R
OW
E
TP
T [°C]
IN
QU
Z

225
POut [%]
200
175
150
125
100
QUINT POWER

C
NF
75
50 = PN 100 %
OK out = PStat. 125 %
DC0% P st
25
= PDyn. 200 %
> 55% Boo
> 700%
>1
2
V Out
Ou d
t1 24
0
SG
Re
14
n
m -25 0 10 20 30 40 50 60 70
Y l
na
Sig
13
T [°C]
,5V
29
Out
U
225
POut [%]
200
175
150
125
QU
IN
100

TP
OW
75
M
E
3x
R
= PN 100 %
8
50
= PStat. 125 %
NFC
DC OK
25
> 50% Pout
= PDyn. 200 %
24V
> 75%
> 100% Boost
Out 2
0
Out 1
SGnd
29,5V
Rem
UOut
14
13
-25 0 10 20 30 40 50 60 70
Signal
Y
T [°C]
Z

16.4.5 Rotated mounting position 90° X-axis
225
POut [%]
200
175
150
125
100
75
= PN 100 %

50
= PStat. 125 %
25
= PDyn. 200 %
0
-25 0 10 20 30 40 50 60 70
Y
T [°C]
Z
16.4.6 Rotated mounting position 270° X-axis

C
F
N
ut
OK Po ost
225
POut [%]
o
DC 50%5% % B
> > 7 00
u >1 t2
V O Out 1 d
n
SG em
24
200
M3x8
l
na R 14
Sig

13
,5V
175
ut
29 U
O
150
125
100
75
= PN 100 %

50
= PStat. 125 %
25
= PDyn. 200 %
0
-25 0 10 20 30 40 50 60 70
Y
T [°C]
Z
107099_en_01 PHOENIX CONTACT GmbH & Co. KG • 32823 Blomberg • Germany 50 / 50

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QUINT4-PS/1AC/24DC/5: Power Supply Unit

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QUINT4-PS/1AC/24DC/5: Power Supply Unit

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QUINT4-PS/1AC/24DC/5

Power supply unit

Can be ordered pre-configured Dimensions W/H/D 36 mm / 130 mm / 125 mm

107099_en_01 PHOENIX CONTACT 2 / 50

Description Type Order No. Pcs./Pkt.

Accessories Type Order No. Pcs./Pkt.

107099_en_01 PHOENIX CONTACT 3 / 50

Accessories Type Order No. Pcs./Pkt.

107099_en_01 PHOENIX CONTACT 4 / 50

Input voltage range 100 V AC ... 240 V AC -15 % ... +10 %

Current draw typ. 1.7 A (100 V AC)

Discharge current to PE < 3.5 mA

107099_en_01 PHOENIX CONTACT 5 / 50

Input protection , AC ( to be connected externally upstream )

Electric strength of the insulation

107099_en_01 PHOENIX CONTACT 6 / 50

Crest factor 120 V AC 230 V AC

Input current vs. output current

= UIn: 120 V AC/UOut: 24 V DC

Input connection data

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Output connection data

Signal contact (configurable)

107099_en_01 PHOENIX CONTACT 8 / 50

Signal connection data

Life expectancy (electrolytic capacitors) 120 V AC 230 V AC

Switching frequency Min. Max.

Power dissipation 120 V AC 230 V AC

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Efficiency 120 V AC 230 V AC

75 = UIn: 120 V AC/UOut: 24 V DC

Ambient temperature (start-up type tested) -40 °C

107099_en_01 PHOENIX CONTACT 10 / 50

Shipbuilding DNV GL, PRS, BV, LR, ABS

107099_en_01 PHOENIX CONTACT 11 / 50

Noise emission for marine approval Minimum normative Higher requirements in

107099_en_01 PHOENIX CONTACT 12 / 50

107099_en_01 PHOENIX CONTACT 13 / 50

107099_en_01 PHOENIX CONTACT 14 / 50

107099_en_01 PHOENIX CONTACT 15 / 50

5 Safety and installation notes The power supply is maintenance-free.

DANGER: Hazardous voltage

CAUTION: Hot surface

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6 High-voltage test (HIPOT) 6.3 High-voltage dielectric test performed by the

High-voltage tests up to 0.8 kV AC /

6.1 High-voltage dielectric test (dielectric strength

6.2 High-voltage dielectric test during the

107099_en_01 PHOENIX CONTACT 17 / 50

For the relevant applicable test voltages and 00

insulation distances, refer to the 5

NFC To disconnect the gas-filled surge arrester, proceed as

No. Designation Color coding Potential DANGER: Risk of electric shock or

107099_en_01 PHOENIX CONTACT 18 / 50

7 Structure of the power supply 7.2 Device dimensions

The fanless convection-cooled power supply can be 36

7.1 Function elements + +

8 Figure 4 Device dimensions (dimensions in mm)

No. Designation 130