Puls CP5.121 Data Sheet

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

1/27

POWER S UPPLY

▪ AC 100-240V Wide-range Input
▪ Width only 32mm
▪ Efficiency up to 94.0%
▪ Excellent Partial Load Efficiency
▪ 20% Output Power Reserves
▪ Easy Fuse Breaking – 3 times nominal current for 12ms
▪ Safe Hiccup

PLUS

Overload Mode

▪ Active Power Factor Correction (PFC)
▪ Minimal Inrush Current Surge
▪ Full Power Between -25°C and +60°C
▪ DC-OK Relay Contact
▪ 3 Year Warranty

PRODUCT DESCRIPTION

SHORT-FORM DATA

Output voltage

DC 12V

Nominal

Adjustment range

12 - 15V

Factory setting 12.0V

Output current

12.0 - 9.6A

Below +45°C ambient

10.0 – 8.0A

At +60°C ambient

7.5 – 6.0A

At +70°C ambient

Derate linearely between +45°C and +70°C

Input voltage AC

AC 100-240V

-15%/+10%

Mains frequency

50-60Hz

±6%

Input current AC

1.09 / 0.6A

At 120 / 230Vac

Power factor

0.98 / 0.91

At 120 / 230Vac

Input voltage DC

DC 110-150V

±20%

Input current DC

1.21A

At 110 / 300Vdc

AC Inrush current

4 / 4A

At 120 / 230Vac

Efficiency

93.2 / 94.0%

At 120 / 230Vac

Losses

8.8 / 7.7W

At 120 / 230Vac

Hold-up time

35 / 35ms

At 120 / 230Vac

Temperature range

-25°C to +70°C

Size (WxHxD)

32x124x102mm

Without DIN-rail

Weight

440g / 0.97lb

ORDER NUMBERS

MAIN APPROVALS

IEC 62368-1

IEC 61010-2-201

The Dimension CP-Series are cost optimized power supplies
without compromising quality, reliability and performance. The
CP-Series is part of the DIMENSION power supply family.

The most outstanding features of this unit is the small size, the
high efficiency, the electronic inrush current limitation, active
PFC and the wide operational temperature range. The device
has a power reserve of 20% included, which may even be used
continuously at temperatures up to +45°C. Additionally, it can
deliver 3 times the nominal output current for 12ms which helps
to trip fuses on faulty output branches.

High immunity to transients and power surges as well as low
electromagnetic emission, a DC-OK signal contact for remote
monitoring, and a large international approval package for a
variety of applications makes this unit suitable for nearly every
situation.

Power Supply CP5.121

Mechanical Accessory

ZM10.WALL Wall/Panel mount bracket

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

For details and a complete approval list see chapter 19.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

2/27

INDEX

TERMINOLOGY AND ABREVIATIONS

Page Page

1. Intended Use ................................................................ 3

2. Installation Instructions ................................................ 3

3. AC-Input ....................................................................... 5

4. DC-Input ....................................................................... 6

5. Input Inrush Current ..................................................... 6

6. Output .......................................................................... 8

7. Hold-up Time .............................................................. 10

8. DC-OK Relay Contact .................................................. 10

9. Efficiency and Power Losses ....................................... 11

10. Functional Diagram .................................................... 12

11. Front Side and User Elements .................................... 12

12. Connection Terminals ................................................ 13

13. Lifetime Expectancy ................................................... 14

14. MTBF .......................................................................... 14

15. EMC ............................................................................ 15

16. Environment ............................................................... 16

17. Safety and Protection Features .................................. 17

The information given in this document is correct to the best of our knowledge and experience at the time of publication. If not
expressly agreed otherwise, this information does not represent a warranty in the legal sense of the word. As the state of our
knowledge and experience is constantly changing, the information in this data sheet is subject to revision. We therefore kindly ask you
to always use the latest issue of this document

No part of this document may be reproduced or utilized in any form without our prior permission in writing.
Packaging and packaging aids can and should always be recycled. The product itself may not be disposed of as domestic refuse.

18. Dielectric Strength ..................................................... 18

19. Approvals and Fulfilled Standards.............................. 19

20. Regulatory Compliance .............................................. 19

21. Physical Dimensions and Weight ............................... 20

22. Accessories................................................................. 21

22.1. ZM10.WALL – Wall/Panel Mount Bracket ........ 21

22.2. YR20.242 - Redundancy Module ...................... 22

23. Application Notes....................................................... 23

23.1. Peak Current Capability .................................... 23

23.2. Charging of Batteries ........................................ 24

23.3. Series Operation ............................................... 24

23.4. Parallel Use to Increase Output Power ............ 24

23.5. Parallel Use for Redundancy ............................ 25

23.6. Operation on Two Phases ................................ 26

23.7. Use in a Tightly Sealed Enclosure ..................... 26

23.8. Mounting Orientations ..................................... 27

PE and symbol PE is the abbreviation for Protective Earth and has the same meaning as the symbol .
Earth, Ground This document uses the term “earth” which is the same as the U.S. term “ground”.
T.b.d. To be defined, value or description will follow later.
AC 230V A figure displayed with the AC or DC before the value represents a nominal voltage with standard tolerances

(usually ±15%) included.
E.g.: DC 12V describes a 12V battery disregarding whether it is full (13.7V) or flat (10V)

230Vac A figure with the unit (Vac) at the end is a momentary figure without any additional tolerances included.
50Hz vs. 60Hz As long as not otherwise stated, AC 230V parameters are valid at 50Hz mains frequency.
may A key word indicating flexibility of choice with no implied preference.
shall A key word indicating a mandatory requirement.
should A key word indicating flexibility of choice with a strongly preferred implementation.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

3/27

1. INTENDED USE

2. INSTALLATION INSTRUCTIONS

WARNING

This device is designed for installation in an enclosure and is intended for commercial use, such as in industrial control, process control,
monitoring and measurement equipment or the like.

Do not use this device in equipment where malfunction may cause severe personal injury or threaten human life.
If this device is used in a manner outside of its specification, the protection provided by the device may be impaired.

Risk of electrical shock, fire, personal injury or death.

- Turn power off before working on the device. Protect against inadvertent re-powering.

- Do not modify or repair the unit.

- Do not open the unit as high voltages are present inside.

- Use caution to prevent any foreign objects from entering the housing.

- Do not use in wet locations or in areas where moisture or condensation can be expected.

- Do not touch during power-on, and immediately after power-off. Hot surfaces may cause burns.

Obey the following installation instructions:

This device may only be installed and put into operation by qualified personnel.
This device does not contain serviceable parts. The tripping of an internal fuse is caused by an internal defect.
If damage or malfunction should occur during installation or operation, immediately turn power off and send unit to the factory for

inspection.
Install the device in an enclosure providing protection against electrical, mechanical and fire hazards.
Install the device onto a DIN-rail according to EN 60715 with the input terminals on the bottom of the device. Other mounting

orientations require a reduction in output current.
Make sure that the wiring is correct by following all local and national codes. Use appropriate copper cables that are designed for a

minimum operating temperature of 60°C for ambient temperatures up to +45°C, 75°C for ambient temperatures up to +60°C and 90°C
for ambient temperatures up to +70°C. Ensure that all strands of a stranded wire enter the terminal connection. Use ferrules for wires
on the input terminals. Unused screw terminals should be securely tightened.

The device is designed for pollution degree 2 areas in controlled environments. No condensation or frost is allowed.
The enclosure of the device provides a degree of protection of IP20.
The isolation of the device is designed to withstand impulse voltages of overvoltage category III according to IEC 60664-1.
The device is designed as “Class of Protection I” equipment according to IEC 61140. Do not use without a proper PE (Protective Earth)

connection.
The device is suitable to be supplied from TN, TT or IT mains networks. The continuous voltage between the input terminal and the PE

potential must not exceed 300Vac.
The input can also be powered from batteries or similar DC sources. The continuous voltage between the supply voltage and the

PE/ground potential must not exceed 360Vdc.
A disconnecting means shall be provided for the input of the device.
The device is designed for convection cooling and does not require an external fan. Do not obstruct airflow and do not cover ventilation

grid!
The device is designed for altitudes up to 5000m (16400ft). Above 2000m (6560ft) a reduction in output current and over voltage

category is required.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

4/27

Keep the following minimum installation clearances: 40mm on top, 20mm on the bottom, 5mm left and right side. Increase the 5mm to
15mm in case the adjacent device is a heat source. When the device is permanently loaded with less than 50%, the 5mm can be reduced
to zero.

The device is designed, tested and approved for branch circuits up to 32A (IEC) and 30A (UL) without additional protection device. If an
external fuse is utilized, do not use circuit breakers smaller than 6A B- or C-Characteristic to avoid a nuisance tripping of the circuit
breaker.

The maximum surrounding air temperature is +70°C (+158°F). The operational temperature is the same as the ambient or surrounding
air temperature and is defined 2cm below the device.

The device is designed to operate in areas between 5% and 95% relative humidity.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

5/27

3. AC-INPUT

AC input

Nom.

AC 100-240V

AC input range

Min.

85-264Vac

Continuous operation

Min.

264-300Vac

Occasionally for maximal 500ms

Allowed voltage L or N to earth

Max.

300Vac

Continuous, according to IEC 606641

Input frequency

Nom.

50–60Hz

±6%

Turn-on voltage

Typ.

80Vac

Steady-state value, see Fig. 3-1

Shut-down voltage

Typ.

74Vac

Steady-state value, see Fig. 3-1

External input protection

See recommendations in chapter 2.

AC 100V

AC 120V

AC 230V

Input current

Typ.

1.30A

1.09A

0.60A

At 12V, 10A, see Fig. 3-3

Power factor

Typ.

0.99

0.98

0.91

At 12V, 10A, see Fig. 3-4

Crest factor

Typ.

1.7

1.8

2.2

At 12V, 10A The crest factor is the
mathematical ratio of the peak value to
RMS value of the input current
waveform.

Start-up delay

Typ.

400ms

350ms

375ms

See Fig. 3-2

Rise time

Typ.

30ms

30ms

30ms

At 12V, 10A const. current load, 0mF
load capacitance, see Fig. 3-2

Typ.

50ms

50ms

50ms

At 12V, 10A const. current load, 10mF
load capacitance,, see Fig. 3-2

Turn-on overshoot

Max.

200mV

200mV

200mV

See Fig. 3-2

Fig. 3-1 Input voltage range

Fig. 3-2 Turn-on behavior, definitions

Turn-on

85V

Rated

input range

max.

500ms

V

IN

P

OUT

300Vac264V

Shut-down

Start-up

delay

Rise

Time

Overshoot

- 5%

Output
Voltage

Input
Voltage

Fig. 3-3 Input current vs. output current at 12V output

voltage

Fig. 3-4 Power factor vs. output current at 12V output

voltage

12A

1 2 4 6 8

0

0.25

0.5

0.75

1.0

1.25

1.5A

Input Current, typ.

10

a) 100Vac
b) 120Vac
c) 230Vac

Output Current

(a)
(b)

(c)

Power Factor, typ.

2 4 6 8 10 12A

0.75

0.8

0.85

0.9

0.95

1.0

Output Current

(a) 100Vac,
(b) 120Vac,
(c) 230Vac

(a)

(b)

(c)

The device is suitable to be supplied from TN, TT or IT mains networks with AC voltage. For suitable DC supply voltages see chapter 4.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

6/27

4. DC-INPUT

DC input

Nom.

DC 110-150V

±20%

DC input range

Min.

88-180Vdc

Continuous operation

DC input current

Typ.

1.21A

At 110Vdc

Allowed Voltage (+) or (-) input to
Earth

Max.

180Vdc

According to IEC 60664-1, continuous operation

Turn-on voltage

Typ.

74Vdc

Steady state value

Shut-down voltage

Typ.

67Vdc

Steady state value

Fig. 4-1 Wiring for DC Input

+

-

Load

L

PE

+

-

Power Supply

AC

DC

Battery

N

5. INPUT INRUSH CURRENT

AC 100V

AC 120V

AC 230V

Inrush current

Max.

8A

peak

7A

peak

7A

peak

At 40°C, cold start

Typ.

5A

peak

4A

peak

4A

peak

At 25°C, cold start

Typ.

5A

peak

5A

peak

6A

peak

At 40°C, cold start

Inrush energy

Max.

0.4A²s

0.5A²s

1A²s

At 40°C, cold start

Fig. 5-1 Typical turn-on behaviour at nominal load,

120Vac input and 25°C ambient

Fig. 5-2 Typical turn-on behaviour at nominal load,
230Vac input and 25°C ambient

The device is suitable to be supplied from a DC input voltage. Use a battery or a similar DC source. A supply from the intermediate DC­bus of a frequency converter is not recommended and can cause a malfunction or damage the unit.

Connect +pole to L, –pole to N and the PE terminal to an earth wire or to the machine ground.

An active inrush limitation circuit (NTCs, which are bypassed by a relay contact) limits the input inrush current after turn-on of the input
voltage.

The charging current into EMI suppression capacitors is disregarded in the first microseconds after switch-on.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

7/27

50ms/DIV

Output voltage

Input
voltage
200V/DIV

Input
current
2A/DIV

4A

50ms/DIV

Input
current
2A/DIV

Input
voltage
200V/DIV

Output voltage

4A

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

8/27

6. OUTPUT

Output voltage

Nom.

12V

Adjustment range

Min.

12-15V

Guaranteed value

Max.

16.0V

This is the maximum output voltage which can occur at
the clockwise end position of the potentiometer due to
tolerances. It is not a guaranteed value which can be
achieved.

Factory settings

Typ.

12.0V

±0.2%, at full load and cold unit

Line regulation

Max.

10mV

Between 85 and 300Vac

Load regulation

Max.

50mV

Between 0A and 12A, static value

Ripple and noise voltage

Max.

50mVpp

Load >0.3A, Bandwidth 20Hz to 20MHz, 50Ohm

Max.

200mVpp

Load <0.3A, Bandwidth 20Hz to 20MHz, 50Ohm

Output current

Nom.

12A1)

At 12V and an ambient temperatures below 45°C

Nom.

10A

At 12V and 60°C ambient temperature

Nom.

7.5A

At 12V and 70°C ambient temperature

Nom.

9.6A1)

At 15V and an ambient temperatures below 45°C

Nom.

8.0A

At 15V and 60°C ambient temperature

Nom.

6.0A

At 15V and 70°C ambient temperature

Derate linearely between +45°C and +70°

Fuse breaking current

Typ.

30A

Up to 12ms once every five seconds, see Fig. 6-2.
The fuse braking current is an enhanced transient current
which helps to trip fuses on faulty output branches. The
output voltage stays above 10V.

Overload behaviour

Continuous current

Output voltage > 7Vdc, see Fig. 6-1

Intermittent current2)

Output voltage < 6Vdc, see Fig. 6-1

Overload/ short-circuit current

Max.

14.2A

Continuous current, see Fig. 6-1

Typ.

15A

Intermitted current peak value for typ. 1s
Load impedance 50mOhm, see Fig. 6-3
Discharge current of output capacitors is not included.

Max.

5A

Intermitted current average value (R.M.S.)
Load impedance 50mOhm, see Fig. 6-3

Output capacitance

Typ.

2 700µF

Included inside the power supply

Back-feeding loads

Max.

25V

The unit is resistant and does not show malfunctioning
when a load feeds back voltage to the power supply. It
does not matter whether the power supply is on or off.
The absorbing energy can be calculated according to the
built-in large sized output capacitor.

The output provides a SELV/PELV rated voltage, which is galvanically isolated from the input voltage.
The device is designed to supply any kind of loads, including capacitive and inductive loads. If extreme large capacitors, such as EDLCs

(electric double layer capacitors or “UltraCaps”) with a capacitance > 0.3F are connected to the output, the unit might charge the
capacitor in an intermittent mode.

The output is electronically protected against overload, no-load and short-circuits. In case of a protection event, audible noise may
occur.

1) This current is also available for temperatures up to +70°C with a duty cycle of 10% and/ or not longer than 1 minute every 10 minutes.

2) At heavy overloads (when output voltage falls below 7V), the power supply delivers continuous output current for 1s. After this, the output is switched off for
approx. 9s before a new start attempt is automatically performed. This cycle is repeated as long as the overload exists. If the overload has been cleared, the
device will operate normally. See Fig. 6-3.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

9/27

Fig. 6-1 Output voltage vs. output current, typ.

Fig. 6-2 Dynamic output current capability, typ.

Output Voltage

0

0 12

2

4

6

15V

8

10

12

20A82 4 10 14 166 18

Adjustment

Range

Output Current

A: continuous current
B: intermittent current

A

B

Output Voltage

(dynamic behavior, < 12ms)

0

0

2

4

6

15V

8

10

12

50A2010 30 405 15 25 35 45

Adjustment

Range

Output Current

Fig. 6-3 Short-circuit on output, Hiccup

PLUS

mode, typ.

Output
Current

0

15A

9s

9s

9s

1s

1s

1s

t

Short -circuit

Normal

operation

Normal

operation

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

10/27

7. HOLD-UP TIME

AC 100V

AC 120V

AC 230V

Hold-up Time

Typ.

70ms

70ms

70ms

At 12V, 5A, see Fig. 7-1

Min.

55ms

55ms

55ms

At 12V, 5A, see Fig. 7-1

Typ.

35ms

35ms

35ms

At 12V, 10A, see Fig. 7-1

Min.

27ms

27ms

27ms

At 12V, 10A, see Fig. 7-1

Fig. 7-1 Hold-up time vs. input voltage

Fig. 7-2 Shut-down behavior, definitions

0

15

30

45

60

90ms

90 120 155 190 230Vac

Input Voltage

75

Hold-up Time

a
b

c
d

a) 12V 5A typ.
b) 12V 5A min.

c) 12V 10A typ.
d) 12V 10A min.

- 5%

Hold-up Time

Zero Transition

Output
Voltage

Input
Voltage

8. DC-OK RELAY CONTACT

Contact closes

As soon as the output voltage reaches typ. 90% of the adjusted output voltage level.

Contact opens

As soon as the output voltage dips more than 10% below the adjusted output voltage.
Short dips will be extended to a signal length of 100ms. Dips shorter than 1ms will be ignored.

Switching hysteresis

Typically 0.4V

Contact ratings

Maximal 60Vdc 0.3A, 30Vdc 1A, 30Vac 0.5A, resistive load

Minimal permissible load: 1mA at 5Vdc

Isolation voltage

See dielectric strength table in section 18.

Fig. 8-1 DC-ok relay contact behavior

100ms

0.9* V

ADJ

<

1ms

10%

open

V

OUT

= V

ADJ

openclosed closed

>

1ms

The hold-up time is the time during which a power supply’s output voltage remains within specification following the loss of input
power. The hold-up time is output load dependent. At no load, the hold-up time can be up to several seconds. The green DC-ok lamp is
also on during this time.

This feature monitors the output voltage on the output terminals of a running power supply.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

11/27

9. EFFICIENCY AND POWER LOSSES

AC 100V

AC 120V

AC 230V

Efficiency

Typ.

92.6%

93.2%

94.0%

At 12V, 10A

Typ.

92.2%

92.9%

93.8%

At 12V, 12A (Power Boost)

Average efficiency*)

Typ.

91.6%

92.0%

92.3%

25% at 2.5A, 25% at 5A,
25% at 7.5A. 25% at 10A

Power losses

Typ.

0.9W

0.9W

1.0W

At 12V, 0A

Typ.

4.9W

4.7W

4.6W

At 12V, 5A

Typ.

9.6W

8.8W

7.7W

At 12V, 10A

Typ.

12.2W

11.0W

9.5W

At 12V, 12A (Power Boost)

Fig. 9-1 Efficiency vs. output current at 12V, typ

Fig. 9-2 Losses vs. output current at 12V, typ.

Efficiency

2 4 6 10 12A

88

89

90

91

92

93

94%

Output Current

8

(a)

(b)

(c)

(a) 100Vac
(b) 120Vac
(c) 230Vac

87
86

Power Losses

0 4 6 12A

2
0

4

6

8

12W

10

10

2 8

Output Current

(a)
(b)

(c)

(a) 100Vac
(b) 120Vac
(c) 230Vac

Fig. 9-3 Efficiency vs. input voltage at 12V, 10A, typ.

Fig. 9-4 Losses vs. input voltage at 12V, 10A, typ.

Efficiency

120 180 230 264Vac

89

90

91

92

Input Voltage

93

94

95%

100

Power Losses

120 180 230 264Vac

5

6

7

8

Input Voltage

9

10

11W

100

*) The average efficiency is an assumption for a typical application where the power supply is loaded with 25% of the nominal load for 25% of the time, 50% of the

nominal load for another 25% of the time, 75% of the nominal load for another 25% of the time and with 100% of the nominal load for the rest of the time.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

12/27

10. FUNCTIONAL DIAGRAM

Fig. 10-1 Functional diagram

+

+

-

-

Output

Over-

Voltage

Protection

PFC

Converter

Output

Voltage

Regulator

Power

Converter

Output

Filter

Output
Voltage
Monitor

Output

Power

Manager

Temper-

ature
Shut-

down

Input Fuse
Input Filter
Input Rectifier
Inrush Current Limiter

V

OUT

L

N

DC-ok
Contact

DC-ok
LED

DC-ok
Relay

11. FRONT SIDE AND USER ELEMENTS

Fig. 11-1 Front side

A Input Terminals
N, L Line input

PE (Protective Earth) input

B Output Terminals

Two identical + poles and two identical - poles

+ Positive output

– Negative (return) output

C Output Voltage Potentiometer

D DC-OK LED (green)

On, when the output voltage is >90% of the adjusted output voltage

E DC-OK Relay Contact

The DC-OK relay contact is synchronized with the DC-OK LED.
See chapter 8 for details.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

13/27

12. CONNECTION TERMINALS

Input

Output

DC-OK-Signal

Type

Screw termination

Screw termination

Push-in termination

Solid wire

Max. 6mm2

Max. 6mm2

Max. 1.5mm2

Stranded wire

Max. 4mm2

Max. 4mm2

Max. 1.5mm2

American Wire Gauge

AWG 20-10

AWG 20-10

AWG 24-16

Max. wire diameter (including ferrules)

2.8mm

2.8mm

1.6mm

Recommended tightening torque

1Nm / 9lb-in

1Nm / 9lb-in

-

Wire stripping length

7mm / 0.28inch

7mm / 0.28inch

7mm / 0.28inch

Screwdriver

3.5mm slotted or cross­head No 2

3.5mm slotted or cross­head No 2

3mm slotted to open the
spring

Fig. 12-1 Daisy chaining of outputs

Fig. 12-2 Using distribution terminals

Load

+

-

Power
Supply

+ +

- -

Output

Power

Supply

+ +

- -

Output

Maximal 25A continuous

Distribution
Terminals

Load

+

-

Power
Supply

+ +

- -

Output

Power
Supply

+ +

- -

Output

The terminals are IP20 Finger safe constructed and suitable for field- and factory wiring.

Daisy chaining:

Daisy chaining (jumping from one power supply output to the next) is allowed as long as the average output current through one
terminal pin does not exceed 25A. If the current is higher, use a separate distribution terminal block as shown in Fig. 12-2.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

14/27

13. LIFETIME EXPECTANCY

AC 100V

AC 120V

AC 230V

Lifetime expectancy

284 000h

297 000h

294 000h

At 12V, 5A and 40°C

804 000h

839 000h

833 000h

At 12V, 5A and 25°C

88 000h

94 000h

110 000h

At 12V, 10A and 40°C

248 000h

267 000h

311 000h

At 12V, 10A and 25°C

44 000h

51 000h

61 000h

At 12V, 12A and 40°C

126 000h

143 000h

171 000h

At 12V, 12A and 25°C

14. MTBF

AC 100V

AC 120V

AC 230V

MTBF SN 29500, IEC 61709

682 000h

687 000h

732 000h

At 12V, 10A and 40°C

1 212 000h

1 221 000h

1 294 000h

At 12V, 10A and 25°C

MTBF MIL HDBK 217F

287 000h

290 000h

308 000h

At 12V, 10A and 40°C;
Ground Benign GB40

417 000h

421 000h

447 000h

At 12V, 10A and 25°C;
Ground Benign GB25

68 000h

69 000h

73 000h

At 12V, 10A and 40°C;
Ground Fixed GF40

91 000h

93 000h

99 000h

At 12V, 10A and 25°C;
Ground Fixed GF25

The Lifetime expectancy shown in the table indicates the minimum operating hours (service life) and is determined by the lifetime
expectancy of the built-in electrolytic capacitors. Lifetime expectancy is specified in operational hours and is calculated according to the
capacitor’s manufacturer specification. The manufacturer of the electrolytic capacitors only guarantees a maximum life of up to 15 years
(131 400h). Any number exceeding this value is a calculated theoretical lifetime which can be used to compare devices.

MTBF stands for Mean Time Between Failure, which is calculated according to statistical device failures, and indicates reliability of a
device. It is the statistical representation of the likelihood of a unit to fail and does not necessarily represent the life of a product.

The MTBF figure is a statistical representation of the likelihood of a device to fail. A MTBF figure of e.g. 1 000 000h means that
statistically one unit will fail every 100 hours if 10 000 units are installed in the field. However, it can not be determined if the failed unit
has been running for 50 000h or only for 100h.

For these types of units the MTTF (Mean Time To Failure) value is the same value as the MTBF value.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

15/27

15. EMC

EMC Immunity

Electrostatic discharge

EN 61000-4-2

Contact discharge
Air discharge

8kV
15kV

Criterion A
Criterion A

Electromagnetic RF field

EN 61000-4-3

80MHz-2.7GHz

20V/m

Criterion A

Fast transients (Burst)

EN 61000-4-4

Input lines
Output lines
DC-OK signal (coupling clamp)

4kV
2kV
2kV

Criterion A
Criterion A
Criterion A

Surge voltage on input

EN 61000-4-5

L → N
L → PE, N → PE

2kV
4kV

Criterion A
Criterion A

Surge voltage on output

EN 61000-4-5

+ → -
+ / - → PE

1kV
2kV

Criterion A
Criterion A

Surge voltage on DC-OK

EN 61000-4-5

DC-OK signal → PE

1kV

Criterion A

Conducted disturbance

EN 61000-4-6

0.15-80MHz

20V

Criterion A

Mains voltage dips

EN 61000-4-11

0% of 100Vac
40% of 100Vac
70% of 100Vac
0% of 200Vac
40% of 200Vac
40% of 200Vac
70% of 200Vac

0Vac, 20ms
40Vac, 200ms
70Vac, 500ms
0Vac, 20ms
80Vac, 200ms <8A
80Vac, 200ms >8A
140Vac, 500ms

Criterion A
Criterion C
Criterion A
Criterion A
Criterion A
Criterion C
Criterion A

Voltage interruptions

EN 61000-4-11

0% of 200Vac (=0V)

5000ms

Criterion C

Powerful transients

VDE 0160

Over entire load range

750V, 0.3ms

Criterion A

EMC Emission

Conducted emission
input lines

EN 55011, EN 55022, FCC Part 15, CISPR 11, CISPR 22

Class B

Conducted emission
output lines

IEC/CISPR 16-1-2, IEC/CISPR 16-2-1

Limits for local DC power networks
fulfilled

Radiated emission

EN 55011, EN 55022

Class B

Harmonic input current (PFC)

EN 61000-3-2

Fulfilled for Class A equipment

Voltage fluctuations, flicker

EN 61000-3-3

Fulfilled, tested with constant
current loads, non pulsing

This device complies with FCC Part 15 rules.
Operation is subjected to following two conditions: (1) this device may not cause harmful interference, and (2) this device must accept
any interference received, including interference that may cause undesired operation.

Switching Frequencies

PFC converter

30kHz to 140kHz

Input voltage and output power dependent

Main converter

60kHz to 140kHz

Output load dependent

Auxiliary converter

30kHz to 60kHz

Output load dependent

The EMC behavior of the device is designed for applications in industrial environment as well as in residential, commercial and light
industry environments.

The device is investigated according to EN 61000-6-1, EN 61000-6-2, EN 61000-6-3 and EN 61000-6-4.

Performance criterions:
A: The device shows normal operation behavior within the defined limits.
C: Temporary loss of function is possible. The device may shut-down and restarts by itself. No damage or hazards for the device will occur.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

16/27

16. ENVIRONMENT

Operational temperature

-25°C to +70°C (-13°F to 158°F)

Operational temperature is the same as the ambient or
surrounding temperature and is defined as the air
temperature 2cm below the unit.

Storage temperature

-40°C to +85°C (-40°F to 185°F)

For storage and transportation

Output de-rating

1.6W/°C
3W/°C

0.67A/1000m or 5°C/1000m

Between +45°C and +60°C (113°F to 140°F)
Between +60°C and +70°C (140°F to 158°F)
For altitudes >2000m (6560ft), see Fig. 16-2

The de-rating is not hardware controlled. The user has to take care by himself to stay below the de-rated
current limits in order not to overload the unit.

Humidity

5 to 95% r.h.

According to IEC 60068-2-30

Atmospheric pressure

110-54kPa

See Fig. 16-2 for details

Altitude

Up to 5000m (16 400ft)

See Fig. 16-2 for details

Over-voltage category

III

According to IEC 60664-1 for altitudes up to 2000m

II

According to IEC 60664-1, for altitudes above 2000m

Degree of pollution

2

According to IEC 62477-1, not conductive

Vibration sinusoidal

2-17.8Hz: ±1.6mm; 17.8-500Hz: 2g
2 hours / axis

According to IEC 60068-2-6

Shock

30g 6ms, 20g 11ms
3 bumps / direction, 18 bumps in total

According to IEC 60068-2-27

Shock and vibration is tested in combination with DIN-Rails according to EN 60715 with a height of
15mm and a thickness of 1.3mm and standard orientation.

LABS compatibility

As a rule, only non-silicon precipitating materials are used. The unit conforms to the LABS criteria and is
suitable for use in paint shops.

Corrosive gases

Tested according to ISA-71.04-1985, Severity Level G3 and IEC 60068-2-60 Test Ke Method 4 for a service
life of minimum 10years in these environments.

Audible noise

Some audible noise may be emitted from the power supply during no load, overload or short circuit.

Fig. 16-1 Output current vs. ambient temp.

Fig. 16-2 Output current vs. altitude

Allowed Output Current at 12V

0

-25 0

45

70°C

7.5A

10A

12A

60

A

Ambient Temperature

A... 85 to 264Vac, continuous
B... short term

B

2000m

5000m

8A

10A

12A

Altitude

Allowed Output Current at 12V

B

A... Tamb < 60°C
B... Tamb < 45°C
C... Short term

A

C

AP

*)

80kPa

54kPa110kPa

0m

*) Atmospheric pressure

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

17/27

17. SAFETY AND PROTECTION FEATURES

Isolation resistance

Min.

500MOhm

At delivered condition between input and output,
measured with 500Vdc

Min.

500MOhm

At delivered condition between input and PE, measured
with 500Vdc

Min.

500MOhm

At delivered condition between output and PE, measured
with 500Vdc

Min.

500MOhm

At delivered condition between output and DC-OK
contacts, measured with 500Vdc

PE resistance

Max.

0.1Ohm

Resistance between PE terminal and the housing in the
area of the DIN-rail mounting bracket.

Output over-voltage protection

Typ.

16.2Vdc

Max.

17Vdc

In case of an internal defect, a redundant circuit limits the maximum output voltage.

The output shuts down and performs three restart attempts. If the failure continues, the
output shuts down. Cycle input power to reset.

Class of protection

I According to IEC 61140
A PE (Protective Earth) connection is required

Degree of protection

IP 20

According to EN/IEC 60529

Over-temperature protection

Included

Output shut-down with automatic restart.
Temperature sensors are installed on critical components
inside the unit and turn the unit off in safety critical
situations, which can happen e.g. when ambient
temperature is too high, ventilation is obstructed or the de­rating requirements are not followed. There is no
correlation between the operating temperature and turn­off temperature since this is dependent on input voltage,
load and installation methods.

Input transient protection

MOV (Metal Oxide
Varistor)

For protection values see chapter 15 (EMC).

Internal input fuse

Included

Not user replaceable slow-blow high-braking capacity fuse

Touch current (leakage current)

Typ.

0.10mA / 0.27mA

At 100Vac, 50Hz, TN-,TT-mains / IT-mains

Typ.

0.13mA / 0.38mA

At 120Vac, 60Hz, TN-,TT-mains / IT-mains

Typ.

0.20mA / 0.60mA

At 230Vac, 50Hz, TN-,TT-mains / IT-mains

Max.

0.13mA / 0.35mA

At 110Vac, 50Hz, TN-,TT-mains / IT-mains

Max.

0.17mA / 0.51mA

At 132Vac, 60Hz, TN-,TT-mains / IT-mains

Max.

0.27mA / 0.81mA

At 264Vac, 50Hz, TN-,TT-mains / IT-mains

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

18/27

18. DIELECTRIC STRENGTH

Fig. 18-1 Dielectric strength

A B C

D

A D

C

B

B

*)

N

L

Input DC-ok

Earth, PE

Output

-

+

Type test

60s

2500Vac

3000Vac

1000Vac

500Vac

Routine test

5s

2500Vac

2500Vac

500Vac

500Vac

Field test

5s

2000Vac

2000Vac

500Vac

500Vac

Field tests cut-off current
settings

> 10mA

> 10mA

> 20mA

> 1mA

B*)
When testing input to DC-OK ensure that the maximal voltage between DC-OK and the output is
not exceeded (column D). We recommend connecting DC-OK pins and the output pins together
when performing the test.

The output voltage is floating and has no ohmic connection to the ground.
The output is insulated to the input by a double or reinforced insulation.
Type and routine tests are conducted by the manufacturer. Field tests may be conducted in the field using the appropriate test

equipment which applies the voltage with a slow ramp (2s up and 2s down). Connect all input-terminals together as well as all output
poles before conducting the test. When testing, set the cut-off current settings to the value in the table below.

We recommend that either the + pole or the – pole shall be connected to the protective earth system. This helps to avoid situations in
which a load starts unexpectedly or cannot be switched off when unnoticed earth faults occur.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

19/27

19. APPROVALS AND FULFILLED STANDARDS

IEC 61010-2-201

CB Scheme Certificate
IEC 61010-2-201 Electrical Equipment for Measurement, Control
and Laboratory Use - Particular requirements for control
equipment

IEC 62368-1

CB Scheme Certificate
IEC 62368-1 Audio/video, information and communication
technology equipment - Safety requirements
Output safety level: ES1

UL 61010-2-201
(former UL 508)

Ind. Cont. Eq.

UL Certificate
Listed equipment for category NMTR - UL 61010-2-201 Electrical
Equipment for Measurement, Control and Laboratory Use ­Particular requirements for control equipment
Applicable for US and Canada
E-File: E198865

EN 60079-0, EN 60079-7
ATEX

Approval for use in hazardous locations Zone 2 Category 3G.
Number of ATEX certificate: EPS 17 ATEX 1 089 X

IEC 60079-0, IEC 60079-7

Suitable for use in Class 1 Zone 2 Groups IIa, IIb and IIc locations.
Number of IECEx certificate: EPS 17.0046X

ANSI / ISA 12.12.01-2007
Class I Div 2

Recognized for use in Hazardous Location Class I Div 2 T4 Groups
A,B,C,D systems; U.S.A. (ANSI / ISA 12.12.01) and Canada (C22.2
No. 213-M1987)

EAC EAC Certificate

EAC EurAsian Conformity Registration Russia, Kazakhstan and
Belarus

20. REGULATORY COMPLIANCE

CE EU Declaration of Conformity

Trade conformity assessment for Europe
The CE mark indicates conformance with the European

- RoHS directive,

- EMC directive and the

- Low-voltage directive (LVD)

REACH Directive

Manufacturer's Statement
EU-Regulation regarding the Registration, Evaluation, Authorisation and
Restriction of Chemicals

WEEE Directive

Manufacturer's Statement
EU-Directive on Waste Electrical and Electronic Equipment

RoHS (China RoHS 2)

Manufacturer's Statement
Administrative Measures for the Restriction of the Use of Hazardous
Substances in Electrical and Electronic Products
25 years

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

20/27

21. PHYSICAL DIMENSIONS AND WEIGHT

Width

32mm 1.26’’

Height

124mm 4.88’’

Depth

102mm 4.02’’
The DIN-rail height must be added to the unit depth to calculate the total required installation depth.

Weight

440g / 0.97lb

DIN-Rail

Use 35mm DIN-rails according to EN 60715 or EN 50022 with a height of 7.5 or 15mm.

Housing material

Body: Aluminium alloy
Cover: zinc-plated steel

Installation clearances

See chapter 2

Penetration protection

Small parts like screws, nuts, etc. with a diameter larger than 3.5mm

Fig. 21-1 Front view Fig. 21-2 Side view

All dimensions in mm

All dimensions in mm

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

21/27

22. ACCESSORIES

Fig. 22-1 Isometric view

Fig. 22-2 Isometric view

Fig. 22-3 Isometric view

Fig. 22-4 Wall/panel mounting, front view

Fig. 22-5 Hole pattern for wall mounting

Fig. 22-6 Wall/panel mounting,

side view

22.1. ZM10.WALL – WALL/PANEL MOUNT BRACKET

This bracket is used to mount the devices on a wall/panel without utilizing a DIN-Rail. The bracket can be mounted without detaching
the DIN-rail brackets.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

22/27

22.2. YR20.242 - REDUNDANCY MODULE

The YR20.242 is a dual redundancy module, which can be used to build 1+1 or N+1 redundant systems.
The device is equipped with two input channels, each rated for 20A for ambient temperatures up to +70°C and are

individually decoupled by utilizing MOSFET technology. The inputs can also be operated up to 24A when the ambient
temperature does not exceed +45°C.

The output can be loaded with nominal 20A at +70°C or 24A at 45°C continuous current.
Using MOSFETSs instead of diodes reduces heat generation, losses and voltage drop between input and output. Due

to these advantages, the unit is very narrow and only requires 32mm width on the DIN-rail.
The device does not require an additional auxiliary voltage and is self-powered even in case of a short circuit across

the output.
See chapter 23.5 for wiring information.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

23/27

23. APPLICATION NOTES

Fig. 23-1 20A peak current for 50ms , typ.

(2x the nominal current)

Fig. 23-2 50A peak current for 5ms , typ.

(5x the nominal current)

10ms/DIV

Output
Voltage

Output
Current

12V

0A

20A

5.9V

1ms/DIV

Output
Voltage

Output
Current

12V

0A

50A

5.6V

Fig. 23-3 30A peak current for 12ms , typ.

(3x the nominal current)

10ms/DIV

Output Voltage

Output Current

12V

0A

12ms

30A

9.7V

Please note: The DC-OK relay triggers when the voltage dips more
than 10% for longer than 1ms.

Peak current voltage dips

Typically from 12V to 5.9V

At 20A for 50ms, resistive load

Typically from 12V to 6V

At 50A for 2ms, resistive load

Typically from 12V to 5.6V

At 50A for 5ms, resistive load

23.1. PEAK CURRENT CAPABILITY

The unit can deliver peak currents (up to several milliseconds) which are higher than the specified short term currents.
This helps to start current demanding loads. Solenoids, contactors and pneumatic modules often have a steady state coil and a pick-up

coil. The inrush current demand of the pick-up coil is several times higher than the steady-state current and usually exceeds the nominal
output current. The same situation applies when starting a capacitive load.

The peak current capability also ensures the safe operation of subsequent circuit breakers of load circuits. The load branches are often
individually protected with circuit breakers or fuses. In case of a short or an overload in one branch circuit, the fuse or circuit breaker
need a certain amount of over-current to open in a timely manner. This avoids voltage loss in adjacent circuits.

The extra current (peak current) is supplied by the power converter and the built-in large sized output capacitors of the power supply.
The capacitors get discharged during such an event, which causes a voltage dip on the output. The following two examples show typical
voltage dips for resistive loads:

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

24/27

Unit A

Unit B

-

+

-

+

Load

+

-

Input

Output

Input

Output

Unit A

Input

Output

Unit B

-

+

-

+

Load

+

-

Input

Output

23.2. CHARGING OF BATTERIES

The power supply can be used to charge lead-acid or maintenance free VRLA batteries.

Instructions for charging batteries:

a) Ensure that the ambient temperature of the power supply stays below 40°C.
b) Use a 15A or 16A circuit breaker or a blocking diode between the power supply and the battery.
c) Ensure that the output current of the power supply is below the allowed charging current of the battery.
d) The return current to the power supply is typically 8mA. This return current can discharge the battery when the power supply is

switched off except in case a blocking diode is utilized.

e) Set the output voltage, measured at no load and at the battery end of the cable, very precisely to the end-of-charge voltage. Set

the output voltage, measured at no load and at the battery end of the cable, very precisely to the end-of-charge voltage. The
voltage should be set to 13.9V at 10°C, 13.75V at 20°C, 13.6V at 30°C and 13.4V at 40°C ambient temperature.

23.3. SERIES OPERATION

Devices of the same type can be connected in series for higher output voltages. It is
possible to connect as many units in series as needed, providing the sum of the output
voltage does not exceed 150Vdc. Voltages with a potential above 60Vdc must be installed
with a protection against touching.

Avoid return voltage (e.g. from a decelerating motor or battery) which is applied to the
output terminals.

Keep an installation clearance of 15mm (left / right) between two power supplies and
avoid installing the power supplies on top of each other. Do not use power supplies in
series in mounting orientations other than the standard mounting orientation.

Pay attention that leakage current, EMI, inrush current, harmonics will increase when using multiple devices.

23.4. PARALLEL USE TO INCREASE OUTPUT POWER

Devises can be paralleled to increase the output power. The output voltage shall be
adjusted to the same value (±100mV) with the same load conditions on all devices, or the
devices can be left with the factory settings.

The ambient temperature is not allowed to exceed +40°C.
If more than three devices are connected in parallel, a fuse or circuit breaker with a rating

of 15A or 16A is required on each output. Alternatively, a diode or redundancy module can
also be utilized.

Energize all devices at the same time. It also might be necessary to cycle the input power
(turn-off for at least five seconds), if the output was in overload or short circuits and the
required output current is higher than the current of one unit.

Keep an installation clearance of 15mm (left / right) between two devices and avoid installing devices on top of each other. Do not use
devices in parallel in mounting orientations other than the standard mounting orientation or in any other condition where a reduction of
the output current is required (e.g. altitude).

Pay attention that leakage current, EMI, inrush current will increase when using multiple devices.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

25/27

Fig. 23-4 1+1 Redundant configuration for 10A load current

with a dual redundancy module

Fig. 23-5 N+1 Redundant configuration for 30A load current with multiple power supplies and

redundancy modules

L
N
PE

10A

Load

Failure

Monitor

I

YR20.242

Redundancy
Module

Output

Input

1

Input

2

+ +

- -

+

-

opt ional

Power
Supply

12V, 10A

DC­OK

+ +

- -

L N PE

Output

Input

o

o

Power
Supply

12V, 10A

DC­OK

+ +

- -

L N PE

Output

Input

o

o

I

L
N
PE

30A

Load

Failure

Monitor

I

YR20.242

Redundancy
Module

Output

Input

1

Input

2

+ +

- -

+

-

opt ional

Power
Supply

12V, 10A

DC­OK

+ +

- -

L N PE

Output

Input

o

o

Power
Supply

12V, 10A

DC­OK

+ +

- -

L N PE

Output

Input

o

o

I

YR20.242

Redundancy
Module

Output

Input

1

Input

2

+ +

- -

+

-

Power
Supply

12V, 10A

DC­OK

+ +

- -

L N PE

Output

Input

o

o

Power
Supply

12V, 10A

DC­OK

+ +

- -

L N PE

Output

Input

o

o

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23.5. PARALLEL USE FOR REDUNDANCY

1+1 Redundancy:

Devices can be paralleled for redundancy to gain higher system availability. Redundant systems require a certain amount of extra power
to support the load in case one device fails. The simplest way is to put two devices in parallel. This is called a 1+1 redundancy. In case
one device fails, the other one is automatically able to support the load current without any interruption. It is essential to use a
redundancy module to decouple devices from each other. This prevents that the defective unit becomes a load for the other device and
the output voltage cannot be maintained any more.

1+1 redundancy allows ambient temperatures up to +70°C.
Pay attention that leakage current, EMI, inrush current, harmonics will increase when using multiple devices.
Recommendations for building redundant power systems:

- Use separate input fuses for each device.

- Use separate mains systems for each device whenever it is possible.

- Monitor the individual devices. Therefore, use the DC-OK signal of the device.

- It is desirable to set the output voltages of all devices to the same value (± 100mV) or leave it at the factory setting.

N+1 Redundancy:

Redundant systems for a higher power demand are usually built in a N+1 method. E.g. four devices, each rated for 10A are paralleled to
build a 30A redundant system.

Pay attention that leakage current, EMI, inrush current, harmonics will increase when using multiple devices.
Keep an installation clearance of 15mm (left / right) between two devices and avoid installing the devices on top of each other.

Do not use devices in parallel in mounting orientations other than the standard mounting orientation or in any other condition, where a
reduction of the output current is required.

For N+1 redundancy the ambient temperature is not allowed to exceed +40°C.

Wiring examples:

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

26/27

Case A

Case B

Enclosure size

110x180x165mm
Rittal Typ IP66 Box
PK 9516 100,
plastic

110x180x165mm
Rittal Typ IP66 Box
PK 9516 100,
plastic

Input voltage

230Vac

230Vac

Load

12V, 8A; (=80%)

12V, 10A; (=100%)

Temperature inside the box

40.7°C

43.2°C

Temperature outside the box

27.9°C

28.0°C

Temperature rise

12.8K

15.2K

240V

+10%

max.

L2

L1

L3

L

N

PE

Power Supply

AC

DC

23.6. OPERATION ON TWO PHASES

The power supply can also be used on two-phases of a three-phase-system. Such a
phase-to-phase connection is allowed as long as the supplying voltage is below

+10%

240V
Ensure that the wire, which is connected to the N-terminal, is appropriately fused.
The maximum allowed voltage between a Phase and the PE must be below 300Vac.

.

23.7. USE IN A TIGHTLY SEALED ENCLOSURE

When the device is installed in a tightly sealed enclosure, the temperature inside the enclosure will be higher than outside. In such
situations, the inside temperature defines the ambient temperature for the device.

In the following test setup, the device is placed in the middle of the box, no other heat producing items are inside the box. The load is
placed outside the box.

The temperature sensor inside the box is placed in the middle of the right side of the power supply with a distance of 1cm.
The following measurement results can be used as a reference to estimate the temperature rise inside the enclosure.

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.

CP5.121

CP-Series

12V, 10A, 120W, SINGLE PHASE INPUT

27/27

Fig. 23-6

Mounting
Orientation A

(Standard
orientation)

Power

Supply

OUTPUT

INPUT

Allowed Output Current at 12V

0

+45 +70°C

7.5A

10A

12A

Ambient Temperature

+60

Fig. 23-7
Mounting
Orientation B
(Upside down)

Power

Supply

OUTPUT

INPUT

Allowed Output Current at 12V

0

+30 +70°C

7.5A

12A

Ambient Temperature

+60

Fig. 23-8
Mounting
Orientation C

(Table-top
mounting)

Allowed Output Current at 12V

0

+25 +70°C

6.5A

12A

Ambient Temperature

+60

Fig. 23-9
Mounting
Orientation D
(Horizontal cw)

Power

Supply

OUTPUT

INPUT

Allowed Output Current at 12V

0

+25 +70°C

6.5A

12A

Ambient Temperature

+60

Fig. 23-10
Mounting
Orientation E
(Horizontal ccw)

Power

Supply

OUTPUT

INPUT

Allowed Output Current at 12V

0

+25 +70°C

6.5A

12A

Ambient Temperature

+60

23.8. MOUNTING ORIENTATIONS

Mounting orientations other than input terminals on the bottom and output on the top require a reduction in continuous output power
or a limitation in the maximum allowed ambient temperature.

The listed lifetime and MTBF values from this datasheet apply only for the standard mounting orientation.
The following curves give an indication for allowed output currents for altitudes up to 2000m (6560ft).

May 2020 / Rev. 1.1 DS-CP5.121-EN All values are typical figures specified at 230Vac, 50Hz input voltage, 12V 10A output load,
25°C ambient and after a 5 minutes run-in time unless otherwise noted.