XP Power CCB250 250 w convection cooled Datasheet

CCB250 Series
•
250 W Convection Cooled
•
300 W Peak Rating 500 ms
•
Very High Efficiency up to 95%
•
1U Form Factor
•
5 V Standby Rail
•
80 V - 275 VAC Input Operation
•
IT & Medical (BF)Safety Approvals
•
Remote On/Off & Power Fail Signal as Standard
The CCB250 range of single output AC-DC 250 W nominal, 300 peak power supplies feature industry leading useable efficiency of
93% and absolute minimum efficiency of 90% with 90 VAC input and full load. This leap in efficiency has been achieved with full
resonant ZCS topology and careful consideration to every aspect of power loss resulting in a convection cooled power supply
packaged in a 6” (153mm) x 4” (102mm) x 1.5” (38mm) open frame design which can be easily installed into end applications due to
a significant reduction in the dissipated heat, associated with other power supplies in this power range.
The six standard models cover the voltage range from 12V - 48V , have dual input fusing and are compliant with IEC60601-1 Medical
(BF) and IEC60950-1 IT safety approvals.
The CCB250 series also boasts low earth leakage current of typically 60 μA at 115V and 110 μA at 230V, class B conducted
emissions, 5V standby rail, power fail signal and remote on / off.
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Models and Ratings - Convection-cooled
Output Power
P nom
P peak
Output Voltage V1
(1)
Output Current V1
I nom
I peak
(1)
Standby Supply
Model Number
CCB250PS12
250 W
300 W
12.0 VDC
20.8 A
25 A
5.0 V/0.5 A
250 W
300 W
15.0 VDC
16.7 A
20 A
5.0 V/0.5 A
CCB250PS15
250 W
300 W
24.0 VDC
10.4 A
12.5 A
5.0 V/0.5 A
CCB250PS24
250 W
300 W
28.0 VDC
8.9 A
10.7 A
5.0 V/0.5 A
CCB250PS28
250 W
300 W
36.0 VDC
6.9 A
8.3 A
5.0 V/0.5 A
CCB250PS36
250 W
300 W
48.0 VDC
5.2 A
6.25 A
5.0 V/0.5 A
CCB250PS48
Notes:
1. Peak duration is 500 ms max, average power must not exceed 250 W.
Input Characteristics
Characteristic
Minimum
Typical
Maximum
Units
Notes & Conditions
Derate output power <90 VAC. See fig 1.
Power fail signal cannot be used <90 VAC.
Input Voltage - Operating
80
115/230
275
VAC
Input Frequency
47
50/60
>0.9
63
Hz
Power Factor
Input Current - No Load
0.13/0.17
Input Current - Full Load
2.4/1.2
Inrush Current
Earth Leakage Current
Input Protection
60/110
EN61000-3-2 class A compliant
A
115/230 VAC
A
115/230 VAC
30
A
230 VAC, 25 °C
250
μA
115/230 VAC/50 Hz (Typ.), 264 VAC/60 Hz (Max.)
T5.0A/250 V internal fuse in both line and neutral
Output Characteristics
Characteristic
Output Voltage - V1
Minimum
Typical
12
Initial Set Accuracy
Output Voltage Adjustment
Minimum Load
Units
Notes & Conditions
48
VDC
See Models and Ratings table
±0.5 (V1) , ±5 (V2)
%
50% load, 115/230 VAC
±3
%
V1 only via potentiometer. See mech. details (page 11).
0
A
Start Up Delay
Hold Up Time
Maximum
0.5
s
16
90 VAC full load (see fig.3)
±0.2
%
After 20 min warm up
Line Regulation
±0.5
%
90-264 VAC
Load Regulation
±1 (V1) , ±5 (V2)
%
0-100% load.
%
Recovery within 1% in less than 500 μs
for a 50-75% and 75-50% load step
Drift
Transient Response - V1
4
Over/Undershoot - V1
Ripple & Noise
5
%
1 (V1), 2 (V2)
% pk-pk
20 MHz bandwidth (see fig.4 & 5)
Overvoltage Protection
115
140
%
Overload Protection
125
165
% I nom
0.05
%/˚C
°C
Auto recovery - temperature of main transformer
100
μA
264 VAC/60 Hz
Short Circuit Protection
Overtemperature Protection
Patient Leakage Current
Vnom DC. Output 1 only, recycle input to reset
Output 1 only, auto reset (see fig.6)
Continuous, trip & restart (hiccup mode) all outputs
Temperature Coefficient
2
230 VAC full load (see fig.2)
ms
110
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Input Voltage Derating
300
Peak Power Availability
Figure. 1
Output Power (W)
250
200
150
100
50
80
85
90
Input Voltage (VAC)
264
275
Start Up Delay From AC Turn On
AC
Figure. 2
V1 & V2 start up example
from AC turn on (580 ms)
V1
V2
Hold Up Time From Loss of AC
Figure 3
V1 hold up example at 250 W load
with 90 VAC input (42 ms)
3
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Output Ripple & Noise
Figure 4
V1 CCB250PS12 (full load)
45 mV pk-pk ripple. 20 MHz BW
Figure 5
V1 CCB250PS24 (full load)
50 mV pk-pk ripple. 20 MHz BW
Output Overload Characteristic
14
12
Figure 6
Typical V1 Overload
Characteristic
(CCB250PS12 shown)
Output Volts (V)
10
Output enters
Trip & Restart Mode
8
6
4
2
0
0
2
4
6
18
20
Output Current (A)
4
22
24
26
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General
Specifications
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Characteristic
Minimum
Typical
Efficiency
Maximum
Units
93
Isolation: Input to Output
Input to Ground
Output to Ground
Notes & Conditions
%
4000
VAC
1500
VAC
1500
Full load (see fig.7 & 8)
VAC
Switching Frequency
30-500 / 25.6 / 51.2
kHz
Power Density
Mean Time Between Failure
Weight
PFC / Boost / Main Converter.
W/in3
6.9
369
kHrs
1.2 (550)
lb (g)
MIL-HDBK-217F, Notice 2
+25 °C GB
100%
100%
90%
90%
80%
80%
Efficiency
Efficiency
Efficiency Versus Load
70%
70%
60%
60%
50%
50%
40%
40%
10
20
30
40
50
60
70
80
90
100
10
20
Load (%)
30
40
50
60
70
80
90
100
Load (%)
230Vac input
230VAC input
Figure 7
CCB250PS12
Figure 8
CCB250PS24
Power Loss
Waste heat creates a big headache for system designers. The industry leading efficiency achieved by the CCB250 is 5-10% above existing topologies
used in this power area. This can result in a 60% reduction in generated heat as shown below and enables the overall system to run much cooler and
more reliably.
Example 2
Example 1
Efficiency
Generated Heat
% Losses
Conventional Products
85 %
44.1 W
100 %
CCB250
93 %
18.8 W
42 %
Efficiency
Generated Heat
% Losses
Conventional Products
90 %
27.8 W
100 %
CCB250
93 %
18.8 W
67 %
5
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Characteristic
Notes & Conditions
Signals
Power Fail
Uncomitted opto isolated transistor, normally off when AC is good (see fig.9 - 11)
Provides ≥ 5 ms (typically 20-30ms) warning of loss of output from AC failure
Remote On/Off (Inhibit/Enable)
Uncommited isolated optocoupler diode, powered diode inhibits the supply (see fig.12-17)
Standby Supply V2
Isolated 5 V/0.5 A supply, always present when AC supplied.
Signals
Power Fail
POWER SUPPLY
Pin 2, 4 & 6
CON 1
5 V Standby
8V Max 3 mA
2K2
Pin 7 CON 1
Power Fail
Collector
Figure 9
Transistor On (<0.8 V): Input & Output Not OK
Transistor Off (>4.5 V): Input & Output OK
Power Fail
Emitter
Pin 8 CON 1
5 V Standby Rtn
Pin 1, 3 & 5
CON 1
Signal Connector
Power Fail
V1
Figure 10
Power Fail signal example at AC switch off
6
Figure 11
V1 warning time example at Power Fail signal 230 VAC
250 W load (37 ms)
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Signals
Remote On/Off (Inhibit/Enable)
POWER SUPPLY
POWER SUPPLY
5 V Standby
2, 4 & 6 CON 1
5 mA
5 V Standby
Pin 2, 4 & 6
CON 1
8 V Max
Inhibit Hi
Pin 10 CON 1
Inhibit Lo
Pin 9 CON 1
8 V Max
Inhibit Hi
Pin 10
CON 1
5 mA
1K
1K
Logic GND
Pin 1, 3 & 5
CON 1
Logic GND Pin
1, 3 & 5 CON 1
Figure 12
Inhibit (Hi)
Inhibit Lo
Pin 9 CH 1
Signal Connector
Figure 13
Inhibit (Lo)
Signal Connector
Inhibit
Figure 14
Example of outputs
switching off when
Inhibit (Lo) configuration
used & switch closed
V1
V2
Inhibit
Figure 15
Example of outputs
switching on when
Inhibit (Lo) configuration
used & switch open
V1
V2
7
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Signals
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Remote On/Off (Inhibit/Enable)
1K
Figure 16
Enable (Hi)
POWER SUPPLY
5 V Standby
Pin 2, 4 & 6 CON 1
1K
Inhibit Hi
Pin 10 CON 1
5 mA
Inhibit Lo
Pin 9
CON 1
Logic GND
Pins 1, 3 & 5 CON 1
Signal Connector
1K
POWER SUPPLY
Figure 17
Enable (Lo)
5 V Standby
Pin 2, 4 & 6, CON 1
1K
Inhibit Hi
Pin 10
CON 1
5 mA
Inhibit Lo
Pin 9
CON 1
Logic GND
Pins 1, 3 & 5, CON 1
Signal Connector
Notes
1. At AC switch on the output (VI) may momentarily rise when the unit is disabled using the 5 V standby in conjunction with the Remote On/Off function.
Environmental
Characteristic
Minimum
Operating Temperature
-20 (-40)
Warm up Temperature
Storage Temperature
Typical
Maximum
Units
+70
°C
20
-40
Operating Altitude
8
Derate linearly from +50 °C at 2.5%/°C
to 50% at 70 °C. See fig.18 & Thermal
Considerations, p.11. (-40 °C consult sales)
Minutes
+85
°C
Convection cooled.
See fig.18 & Thermal Considerations, p.11.
Cooling
Humidity
Notes & Conditions
5
95
%RH
3000
m
Non-condensing
Shock
3 x 30 g/11 ms shocks in both +ve & -ve
directions along the 3 orthogonal axis,
total 18 shocks.
Vibration
Single axis 10-500 Hz at 2 g x 10 sweeps
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Derating Curve
300
Figure 18
Output Power (W)
Peak Power Availability
250
200
150
100
50
0
-20
-10
10
Ambient Temperature (°C)
0
40
50
60
70
Electromagnetic Compatibility - Immunity
Phenomenon
Standard
Test Level
Criteria
EN61204-3
High severity level
as below
Harmonic Current
EN61000-3-2
Class A
Radiated
EN61000-4-3
3
EFT
EN61000-4-4
3
A
Surges
EN61000-4-5
Installation class 3
A
Conducted
EN61000-4-6
3
A
Low Voltage PSU EMC
EN61000-4-11
Dips and Interruptions
EN60601-1-2
(EN61000-4-11)
Notes & Conditions
A
Dip:
30% 10 ms
A
Dip:
60% 100 ms
B
Dip: 100% 5000 ms
B
Dip:
30% 500 ms
A
Dip:
60% 100 ms
A
Dip:
100% 10 ms
A
Int.: >95% 5000 ms
B
Requires load derating to approx 80% with
115 VAC input.
Electromagnetic Compatibility - Emissions
Phenomenon
Standard
Test Level
Conducted
EN55022
Class B
EN55022
Class A
Radiated
Voltage Fluctuations
Criteria
Notes & Conditions
See fig. 19
EN61000-3-3
9
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Typical EMC Plot
Figure 19 - Typical conducted noise plot
Safety Agency Approvals
Safety Agency
Safety Standard
Category
CB Report
Certificate # US/17818/UL IEC60950-1:2005 Ed 2
Information Technology
UL
UL File #E139109-A62-UL UL60950-1 (2007), CSA 22.2 No.60950-1-07 Ed 2
Information Technology
TUV
TUV Certificate # B11 10 57396 113, EN60950-1:2010
Information Technology
CE
LVD
Safety Agency
Safety Standard
Category
CB Report
Certificate #US/18197/UL, IEC60601-1 Ed 3 Including Risk Management
Medical
UL
UL File # E146893, ANSI/AAMI ES 60601-1:2005 & CSA C22.2 No. 60601-1:08
Medical
TUV
TUV Certificate # B11 12 57396 124, EN60601-1:2006
Medical
Primary to Secondary
2 x MOPP (Means of Patient Protection)
Primary to Earth
1 x MOPP (Means of Patient Protection)
Secondary to Earth
1 x MOPP (Means of Patient Protection)
Equipment Protection Class
Safety Standard
Notes & Conditions
IEC60950-1:2005 Ed 2 & IEC60601-1 Ed 3
See safety agency conditions of
acceptability for details
Means of Protection
Class I & BF
10
Category
IEC60601-1 Ed 3
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Xxxxxxxxxx Details
Mechanical
6.00 (152.4)
0.24
(6.1)
Output
Voltage
Adjustment
Signal Connector*
ø 3.5
through
4 places
L2
-VE
CON 3
3.73
(94.6)
C12
101.6
(4.0)
Output
connectors
allow
connections
from either
top or side
L
CON 4 N
0.74
(19.0)
0.14
(3.5)
E
0.14
(3.5)
5.73 (145.42)
1.98
(50.4)
Output Terminals
M4 Screws in
2 positions
torque to 8 lbs-in
(90 cNm) max
C21
Pin 2
38.1
(1.5)
Mounting holes married with
must be connected to safety earth.
+VE
2.60
(66.3)
Pin 1
Pin 10
Pin 9
*Signal Connector
CON 1 10-way
JST-BI0B-PHDSS
Mating Half - p/n
JST PHDR-10VS,
Contact- 26-22 AWG
p/n JST SPHD-001T-P0.5
Signals Connector CON 1
1
Input Connector CON 4
Pin 1
Line
Pin 2
Neutral
Pin 3
Earth
Notes
1. All dimensions in inches (mm).
Tolerance .xx = ±0.02 (0.50); .xxx = ±0.01 (0.25)
CON 4 mates with Molex housing
09-50-1051 and Molex series 5194
crimp terminals.
Weight 1.2 lb (550 g) approx
1
2
Output Connector CON 3
+V1
V 1 RTN
5 V Standby Return
2
5 V Standby
3
5 V Standby Return
4
5 V Standby
5
5 V Standby Return
6
5 V Standby
7
Power Fail (Collector)
8
Power Fail (Emitter)
9
Remote On / Off (Cathode)
10
Remote On / Off (Anode)
CON 1 mates with JST housing
PHDR-10VS with
contact SPHD-001T-P0.5
11
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Thermal Considerations
In order to ensure safe operation of the PSU in the end-use equipment, the temperature of the components listed in the table below must not be
exceeded. Temperature should be monitored using K type thermocouples placed on the hottest part of the component (out of any direct air flow). See
Mechanical Details for component locations.
Temperature Measurements (Ambient ≤ 50 ºC)
Component
Max Temperature ºC
L2
120 ºC
C12
105 ºC
C21
105 ºC
Service Life
The estimated service life of the CCB250 Series is determined by the cooling arrangements and load conditions experienced in the end application.
Due to the uncertain nature of the end application this estimated service life is based on the actual measured temperature of a key capacitor within the
product when installed in the end application.
The graph below expresses the estimated lifetime for a given component temperature and assumes continuous operation at this temperature.
Estimated Service Life vs Component Temperature
Figure 20
185000
165000
Lifetime (Hrs)
145000
125000
105000
85000
65000
45000
25000
5000
105
95
85
75
65
55
C64 Temperature (°C)
12
23-Sep-13
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