MURATA ULE-48/1.25-D48N-C

ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
The ULE Series "Eighth-Brick" DC/DC Converters are high-current isolated
power converters designed for use in high-density system boards.
Typical unit
FEATURES
PRODUCT OVERVIEW
RoHS compliant
Measuring just 0.89 × 2.22 × 0.36 inches (22.6
× 56.4 × 9.1mm), these open-frame, low-profile
E-bricks fit the industry-standard quarter-brick
footprint. Now you can “cut-and-paste” the layout
from your last Q-brick design to save time and save
44% board space (1.86 square inches versus 3.3)
in the process.
From a 9-18V, 18-36V or 36-75V input, ULEs
deliver 1.2 to 48 Volt outputs with current up to
30 Amps. They employ an interleaved, synchronous-rectifier topology that exploits 100% of their
duty cycle. They simultaneously achieve high
efficiency, low noise, tight line/load regulation, and
quick step response.
An open-frame design, high efficiency, low-onresistance FETs, and planar magnetics embedded
New 1/8-brick package, 1/4-brick pinout
in through-hole or SMT version
0.89 x 2.22 x 0.36 in. (22.6 x 56.4 x 9.1mm)
Output current: 1.25-30 Amps
Output voltages: 1.2V to 48V
Input voltage: 12V, 24V and 48V nominal
Interleaved, synchronous-rectifier
topology delivers:
• Outstanding efficiency (to 94%)
• Low noise
• Stable no-load operation
• No output reverse conduction
Excellent thermal performance
in heavy-copper pc boards all contribute to
impressive thermal derating. The ULEs feature set
includes high isolation (2250Vdc, 48V models),
input pi filters, input undervoltage shutdown,
output overvoltage protection, current limiting,
short-circuit protection, and thermal shutdown. The
standard footprint carries VOUT trim, on/off control,
and sense pins (sense pins are not available on
12V or higher models).
All ULE E-Bricks are designed to meet the BASICinsulation requirements of UL/EN/IEC60950-1, and
all “D48” models (36-75V input ranges) carry the
CE mark. Safety certifications, EMC compliance
testing and qualification testing are available.
On/off control, trim and sense pins
Fully isolated (2250Vdc BASIC)
Fully I/O protected; Thermal shutdown
Designed to meet UL/IEC/EN 60950-1 and
CAN/CSA C22.2 No.60950-1
Lead-free construction/attach
NOTE: See pages 19 and 20 for simplified block diagrams.
For full details go to
www.murata-ps.com/rohs
www.murata-ps.com
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDC_ULE Series.C11 Page 1 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
PERFORMANCE SPECIFICATIONS AND ORDERING GUIDE
Output
Input
Power R/N (mVp-p) €
(W)
Typ.
Max.
Regulation (Max.)
IIN no
load
(mA)
IIN full
load
(A)
VOUT
(V)
IOUT
(A)
ULE-1.2/30-D48N-C 1.2
30
36
ULE-1.5/20-D24P-C
1.5
20
30
25
60
±0.15%
±0.15%
24
18-36
40
ULE-1.5/20-D48N-C
1.5
20
30
25
60
±0.15%
±0.15%
48
36-75
ULE-1.8/20-D24P-C
1.8
20
36
40
80
±0.25%
±0.25%
24
ULE-1.8/20-D48N-C
1.8
20
36
40
80
±0.25%
±0.25%
ULE-2.5/20-D24P-C
2.5
20
50
30
50
±0.05%
±0.05%
ULE-2.5/20-D48N-C
2.5
20
50
50
75
±0.05%
±0.1%
48
36-75
55
1.17
88.0%
89.0%
C56, C52, P32
ULE-3.3/20-D12P-C
3.3
20 66
60
100
±0.05%
±0.05%
12
9-18 100
6.15
88.9%
89.4%
C56, C52, P32
ULE-3.3/20-D24P-C
3.3
20
66
50
80
±0.05%
±0.05%
24
18-36
60
3.09
88.0%
89.0%
C56, C52, P32
ULE-3.3/20-D48N-C
3.3
20
66
50
100
±0.1%
±0.25%
48
36-75
60
1.54
87.0%
89.0%
C56, C52, P32
5
10
50
60
125
±0.05%
±0.05%
12
9-18
160
4.63
87.0%
90.0%
C56, C52, P32
ULE-5/12-D24P-C
5
12 60
50
100
±0.1%
±0.25%
24
19-36 160
2.78
88.0%
90.0%
C56, C52, P32
ULE-5/12-D48N-C
5
12
60
50
100
±0.1%
±0.25%
48
36-75
90
1.38
88.5%
90.5%
C56, C52, P32
Model Family ULE-5/10-D12P-C
Line
Load
VIN Nom. Range
(V)
(V)
Efficiency
Package
(Case, Pinout)
Min.
Typ.
1.42
86.0%
88.0%
C56, C52, P32
40
0.74
84.0%
84.5%
C56, C52, P32
18-36
40
1.74
84.5%
86.0%
C56, C52, P32
48
36-75
40
0.87
84.5%
86.5%
C56, C52, P32
24
18-36
95
2.35
87.0%
88.5%
C56, C52, P32
Please contact Murata Power Solutions for further information.
C56, C52, P32
ULE-12/4.2-D24P-C
12
4.2 50.4
50
150
±0.05%
±0.075%
24
18-36
55
2.31
89.5%
91.0%
C56, C52, P32
ULE-12/4.2-D48N-C
12
4.2
50.4
50
150
±0.05%
±0.075%
48
36-75
55
1.14
91.0%
92.0%
C56, C52, P32
ULE-24/3-D48N-C
24
3
72
400
700
±0.3%
±0.875%
48
36-75
45
1.63
90.8%
92.0%
C56, C52, P32
ULE-48/1.25-D48N-C
48
1.25
60
640
750
±0.175%
±3.2%
48
36-75
75
1.35
91.0%
92.5%
C56, P32
Please refer to the full model number structure for additional ordering part numbers and
If VIN = 19−20V, IOUT = 8A Max.
Min. load = 10%.
If VIN = 9−10V, IOUT = 18A Max.
options.
Preliminary specifications − please contact MPS for availability.
All specifications are at nominal line voltage and full load, +25ºC unless otherwise noted.
See detailed specifications.
PART NUMBER STRUCTURE
U LE - 1.2 / 30 - D48 N M Lx - C
RoHS-6 hazardous substance compliant
Output Configuration:
U = Unipolar/Single
Pin Length Option (Through-hole packages only)
Eighth-Brick Package
Blank = standard length 0.180 inches (4.6mm)
L1 Pin length 0.110±0.010 inches (2.79±0.25mm)*
L2 Pin length 0.145±0.010 inches (3.68±0.25mm)*
*Minimum order quantity required.
Nominal Output Voltage
Surface Mount Package
Maximum Rated Output
Current in Amps
Input Voltage Range:
D12 = 12V nominal
D24 = 24V nominal
D48 = 48V nominal
Note:
Some model number combinations may
not be available. Contact Murata Power
Solutions for further information.
20
Remote On/Off Control Polarity:
P = Positive polarity (standard for D12 and
D24 models, optional special order for D48 models)
N = Negative polarity (standard for D48 models,
optional special order for D12 and D24 models)
See notes on page 5.
www.murata-ps.com
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDC_ULE Series.C11 Page 2 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
INPUT CHARACTERISTICS
Load Current
Remote On/Off Control
Under Reflected
InterStart-up Voltage (back)
Full
Inrush
nal Reverse
Positive
Negative
threshold Shut- Ripple
Load Transient Output
Low Standby Input Polarity CurLogic
Logic
Min.
down Current Condi- Conditions Short No Load Line Mode Filter Protec- rent
“P” model
“N” model
Model Family (V)
(V)
(mA)
tions (A2sec) Circuit (mA) (A) (mA) Type tion (mA)
suffix
suffix
ULE-1.2/30-D48 34.0
33.0
1.20
ULE-1.5/20-D24 17.0
16.0
1.96
ULE-1.5/20-D48
34.0
33.0
0.98
ULE-1.8/20-D24 17.0
16.0
2.33
ULE-1.8/20-D48
33.0
31.0
1.16
ULE-2.5/20-D24
17.0
16.0
3.23
ULE-2.5/20-D48
33.0
32.0
ULE-3.3/20-D12
8.5
8.0
Start-up Time
VIN to VOUT Remote On/Off
regulated to VOUT regu(Max.)
lated (Max.)
mSec
mSec
1.55
40−250 40−160 7.42 1−8
model model
model
4.10
depen- dependependent
dent 2.05 dent
OFF=Ground pin OFF=open or 6-90, model
to +0.8V max.
+3.5V to
dependent
1.0
ON=open or
+13.5V max.
3.5V to +13.5V ON=Ground pin
max.
to +0.8V max.
6-90, model
dependent
ULE-3.3/20-D24
17.0
ULE-3.3/20-D48
34.5
15−45,
See
model Ordering
16.0
dependent Guide
33.5
ULE-5/10-D12
8.5
8.0
6.14
ULE-5/12-D24
19.0
17.5
3.30
ULE-5/12-D48
34.5
33.5
1.82
ULE-12/4.2-D24
17.0
16.0
3.04
ULE-12/4.2-D48
35.0
34.0
1.51
ULE-24/3-D48
35.0
33.0
2.17
150
150
ULE-48/1.25-D48
35.0
33.5
1.46
6-90
6-90
0.5−1
L-C
See
Notes
OUTPUT CHARACTERISTICS
Model Family
Capacitive Loading
Max.
VOUT
Accuracy Low ESR <0.02Ω Max.
resistive load
VOUT 50% Load
(μF)
(V) % of VNOM
Adjustment
Range
Temperature
Coefficient
Minimum
Loading
Ripple/Noise
Remote Sense
(20 MHz
Line/Load
Compensation bandwidth)
Regulation
Efficiency
Current Limit
Inception
98% of VOUT
after warmup
(A)
ULE-1.2/30-D48
1.2
34
ULE-1.5/20-D24
1.5
24
ULE-1.5/20-D48
1.5
24
ULE-1.8/20-D24
1.8
24
ULE-1.8/20-D48
1.8
25
ULE-2.5/20-D24
2.5
ULE-2.5/20-D48
2.5
ULE-3.3/20-D12
±1 to ±2
of VNOM,
3.3
model
3.3 dependent
ULE-3.3/20-D24
ULE-3.3/20-D48
24
10,000
3.3
+10%
−20 to +10%
±0.02% of
of VNOM, model
VOUT range/°C
dependent
24
No Minimum
Load18
24
See Ordering Guide
24
26
ULE-5/10-D12
5
13
ULE-5/12-D24
5
15
16
ULE-5/12-D48
5
ULE-12/4.2-D24
12
ULE-12/4.2-D48
12
ULE-24/3-D48
24
680
300 mA
10%
4.25
ULE-48/1.25-D48
48
470
No Minimum
none
2.5
2000
none
6
6.25
See notes on page 5.
www.murata-ps.com
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDC_ULE Series.C11 Page 3 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
ISOLATION CHARACTERISTICS
Model Family
DYNAMIC CHARACTERISTICS
Input to
Output
Min.
(V)
Isolation
Resistance
(MΩ)
Isolation
Capacitance
Isolation
(pF)
Safety Rating
Model Family
Switching
Frequency
KHz
Dynamic Load Response
(50-75-50% load step)
ULE-1.2/30-D48
ULE-1.2/30-D48
100μSec to ±1% of final value
260±15
ULE-1.5/20-D24
ULE-1.5/20-D24
100μSec to ±1.5% of final value
280±15
ULE-1.5/20-D48
ULE-1.5/20-D48
100μSec to ±1.5% of final value
280±15
ULE-1.8/20-D24
ULE-1.8/20-D24
100μSec to ±1.5% of final value
340±15
ULE-1.8/20-D48
100μSec to ±1.5% of final value
340±15
ULE-2.5/20-D24
150μSec to ±1% of final value
385±15
ULE-2.5/20-D48
80μSec to ±1.5% of final value
385±45
ULE-3.3/20-D12
150μSec to ±1.25% of final value
310±15
ULE-3.3/20-D24
150μSec to ±1.5% of final value
385±15
ULE-3.3/20-D48
150μSec to ±1% of final value
365±15
ULE-5/10-D12
75μSec to ±2% of final value
325±15
ULE-5/12-D24
75μSec to ±2% of final value
450±15
ULE-5/12-D48
100μSec to ±1% of final value
450±15
ULE-12/4.2-D24
150μSec to ±1.25% of final value
400±15
ULE-12/4.2-D48
150μSec to ±1.25% of final value
380±15
ULE-1.8/20-D48
1750
ULE-2.5/20-D24
ULE-2.5/20-D48
ULE-3.3/20-D12
ULE-3.3/20-D24
ULE-3.3/20-D48
20002250 min.,
model
dependent
Basic
Insulation
100
ULE-5/10-D12
470
ULE-5/12-D24
ULE-5/12-D48
ULE-12/4.2-D24
1750
ULE-12/4.2-D48
ULE-24/3-D48
2000
ULE-24/3-D48
200μSec to ±2% of final value
240±30
ULE-48/1.25-D48
1500
ULE-48/1.25-D48
200μSec to ±1% of final value
250±15
MISCELLANEOUS CHARACTERISTICS
Operating Temperature Range
Model Family
Calculated
MTBF
See
derating curves
Operating PCB
Storage
Temperature Temperature
(no derating)
Range
Thermal
Protection/
Shutdown
Short
Circuit
Current
Overvoltage
Protection12
via magnetic Short Circuit
feedback
Protection Short Circuit
(V)
Method Duration16
ULE-1.2/30-D48
3A
2.0
ULE-1.5/20-D24
3A
2.3
ULE-1.5/20-D48
3A
2.0
ULE-1.8/20-D24
3A
2.3
ULE-1.8/20-D48
3A
2.3
ULE-2.5/20-D24
3A
3.5
ULE-2.5/20-D48
3A
3.0
300mA
3.96
3A
3.96
ULE-3.3/20-D12
ULE-3.3/20-D24
TBC
−40 to +85ºC with derating
−40 to
+105ºC
−55 to
+125ºC
ULE-3.3/20-D48
+105 to
+125ºC,
model
dependent
3A
3.96
ULE-5/10-D12
5A
6.0
ULE-5/12-D24
5A
6.0
ULE-5/12-D48
2A
6.4
ULE-12/4.2-D24
3A
15.0
ULE-12/4.2-D48
3A
14.0
ULE-24/3-D48*
0.65A
28.0
ULE-48/1.25-D48
500mA
55.0
Current
limiting,
hiccup
autorestart.
Remove
overload for
recovery
Continuous,
output
shorted to
ground.
No damage.
Relative
Humidity
To
+85ºC/85%
noncondensing
*No derating is required up to 85°C.
See notes on page 5.
www.murata-ps.com
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDC_ULE Series.C11 Page 4 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
PERFORMANCE SPECIFICATION NOTES
1. All models are tested and specified with external 1||10 μF ceramic/tantalum output
capacitors and a 22 μF external input capacitor. All capacitors are low ESR types.
These capacitors are necessary to accommodate our test equipment and may
not be required to achieve specified performance in your applications. All models
are stable and regulate within spec under no-load conditions. General conditions
for Specifications are +25 deg.C, VIN=nominal, VOUT=nominal, full load. Adequate
airflow must be supplied for extended testing under power.
2. Input Ripple Current is tested and specified over a 5 Hz to 20 MHz bandwidth. Input
filtering is CIN=33 μF tantalum, CBUS=220 μF electrolytic, LBUS=12 μH.
3. Note that Maximum Power Derating curves indicate an average current at nominal
input voltage. At higher temperatures and/or lower airflow, the DC/DC converter will
tolerate brief full current outputs if the total RMS current over time does not exceed
the Derating curve. All Derating curves are presented at sea level altitude. Be aware
of reduced power dissipation with increasing density altitude.
4. Mean Time Before Failure is calculated using the Telcordia (Belcore) SR-332 Method 1,
Case 3, ground fixed conditions, Tpcboard=+25ºC, full output load, natural air convection.
5. The On/Off Control is normally controlled by a switch. But it may also be driven with
external logic or by applying appropriate external voltages which are referenced to
Input Common. The On/Off Control Input should use either an open collector or open
drain transistor.
6. Short circuit shutdown begins when the output voltage degrades approximately 2%
from the selected setting.
7. The outputs are not intended to sink appreciable reverse current..
8. Output noise may be further reduced by adding an external filter. See I/O Filtering
and Noise Reduction.
9. All models are fully operational and meet published specifications, including “cold
start” at –40ºC.
10. Regulation specifications describe the deviation as the line input voltage or output
load current is varied from a nominal midpoint value to either extreme.
11. Alternate pin length and/or other output voltages are available under special quantity
order.
12. Electronic overvoltage shutdown is not included on 48V input models to comply
with certain telecom reliability requirements. These requirements attempt continued
operation despite input overvoltage. The converter is rated only to the maximum
input voltage.
13. Do not exceed maximum power specifications when adjusting the output trim.
14. At zero output current, the output may contain low frequency components which
exceed the ripple specification. The output may be operated indefinitely with no load.
15. If reverse polarity is accidentally applied to the input, a body diode will become
forward biased and will conduct considerable current. To ensure reverse input
protection with full output load, always connect an external input fuse in series with
the +VIN input. Use approximately twice the full input current rating with nominal
input voltage.
16. Output current limit is non-latching. When the overcurrent fault is removed, the
converter will immediately recover.
17. The Sense inputs are not included on 12V, 24V & 48V input models.
18. ULE-12/4.2-D24 minimum load is 0.42 Amps (10%) for rated specifications.
19. ULE-5/12-D24 IOUT=8A max. if VIN=19-20V.
20. ULE-12/4.2-D48 has no surface mount option.
21. Full load conditions, see ordering guide.
PHYSICAL CHARACTERISTICS AND SAFETY
Outline dimensions
See mechanical specs (below)
Pin material
Copper alloy
Pin diameter
0.04/0.062" (1.016/1.524mm)
Pin finish
Nickel underplate with gold overplate
Weight
1 ounce (28 grams)
Electromagnetic interference (conducted and radiated)
(external filter required)
Designed to meet FCC part 15, class B, EN55022
Safety
Designed to meet UL/cUL 60950-1, CSA-C22.2 No. 60950-1, IEC/EN 60950-1
www.murata-ps.com
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDC_ULE Series.C11 Page 5 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
MECHANICAL SPECIFICATIONS
Through-hole Pin Changes for 2008
In 2008, for through-hole models only, MPS will gradually phase over to a different extruded 0.040” (1.02 mm) diameter pin design and elimination of the
spacer standoffs on most models. This will have no effect on installation,
interchangeability, electrical or mechanical specifications. Any machined
0.062” (1.57 mm) diameter pin will transition to a straight wire 0.062” pin. The
new 0.040” pins will insert properly to existing host PC boards and include an
integral pin shoulder to form the mounting plane (Figure 1). There is no model
number change, only a slightly changed appearance. Use the drawings and table
below to identify the new pin design. Older drawings are retained in this data
sheet for archival reference. And, surface mount ULEs are not affected.
All new production models are RoHS-6 compliant and always use the –C
model number suffix. Older non-RoHS models are also being changed over to
the new extruded pins; however non-RoHS models are not listed in this table.
0.040 (1.02) dia. pin
Pin shoulder, 0.072 ±0.002 dia. (1.83 ±0.05)
ULE Converter
Seating plane
User’s host
PC Board
Keep-out area
Pin depth, see table
Dimensions are in inches (mm)
Drawing not to scale
Figure 1. Extruded 0.040-inch Pin
Extruded 0.040-inch Pin Configurations
RoHS Models (-C)
ULE-1.2/30-D48
ULE-1.5/20-D24P
ULE-1.5/20-D48
ULE-1.8/20-D24
ULE-1.8/20-D48
ULE-2.5/20-D24
ULE-2.5/20-D48
ULE-3.3/20-D12
ULE-3.3/20-D24
ULE-3.3/20-D48N
ULE-3.3/20-D48P
ULE-5/10-D12
ULE-5/12-D24
ULE-5/12-D48
ULE-12/4.2-D24
ULE-12/4.2-D48
ULE-24/3-D48N
ULE-48/1.25-D48
0.040" Pin depth*
0.25 (6.4)
0.25 (6.4)
0.25 (6.4)
0.25 (6.4)
0.25 (6.4)
0.19 (4.8)
0.19 (4.8)
0.19 (4.8)
0.25 (6.4)
0.25 (6.4)
0.19 (4.8)
0.19 (4.8)
0.19 (4.8)
0.25 (6.4)
0.25 (6.4)
0.25 (6.4)
0.25 (6.4)
0.25 (6.4)
*The “0.040-inch pin depth” is the distance between the mounting plane of the ULE
converter (at the pin shoulder) and the inserted tip of the pin. Therefore it is the length of
pin which the host receiving PC board must accept. The ULE mounting plane interfaces
to the top mounting surface (seating plane) of the user’s PC board. The ULE mounting
plane is established either by an integral pin shoulder (new) or a plastic standoff (older)
but not both. Users should avoid placing components immediately below the converter.
**Dimensions in inches (mm)
The “integral” pin shoulder is formed as part of the extruded pin fabrication and replaces the plastic standoff spacer. The shoulder diameter is 0.072
+/−0.002" and forms the mounting plane of the converter. The user should
provide sufficient clearance for a 0.040" pin hole but well below the 0.072"
shoulder diameter. This mounting plane avoids mechanical stress placed on
the converter components. Do not place the components below the converter.
The pin finish for all models remains as gold plate over nickel underplate.
The pin material is a copper alloy. The pin finish is suitable for both leaded
and lead-free solders.
PIN STRUCTURE DIMENSIONS (NO LONGER USED)
ULE-12/4.2-D48
ULE-5/12-D48
(machined pins only)
0.26 ±0.02 (6.6 ±0.5)
Printed Circuit Board
Ø 0.08 ±0.002 (2.1 ±0.05)
Ø 0.06 ±0.002 (1.6 ±0.05)
0.19 ±0.005 (4.8 ±0.1)
Ø 0.06 ±0.001 (1.5 ±0.03)
Ø 0.04 ±0.001 (1 ±0.03)
Standard Pins (6)
Dimensions are in inches (mm)
VOUT Pins (2)
Drawing not to scale
This is an older pin design. This drawing is retained for archival purposes only.
Please refer to the Pin Change discussion.
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MDC_ULE Series.C11 Page 6 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
MECHANICAL SPECIFICATIONS (continued)
Input/Output Connections
ULE Mechanical Dimensions
Model Family
ULE-1.2/30-D48
ULE-1.5/20-D24
ULE-1.5/20-D24M <SMT>
ULE-1.5/20-D48
ULE-1.5/20-D48M <SMT>
ULE-1.8/20-D24
ULE-1.8/20-D24M <SMT>
ULE-1.8/20-D48
ULE-1.8/20-D48M <SMT>
ULE-2.5/20-D24, -D48
ULE-2.5/20-D24M <SMT>
ULE-3.3/20-D12, -D48
ULE-3.3/20-D12M <SMT>
ULE-3.3/20-D24
Height (Max.)*
0.365 (9.27)
0.404 (10.26)
0.404 (10.26)
0.381 (9.68)
0.404 (10.26)
0.404 (10.26)
0.404 (10.26)
0.381 (9.68)
0.404 (10.26)
0.409 (10.39)
0.404 (10.26)
0.409 (10.39)
0.404 (10.26)
0.381 (9.68)
Model Family
ULE-3.3/20-D24M <SMT>
ULE-3.3/20-D48M <SMT>
ULE-5/10-D12
ULE-5/10-D12M <SMT>
ULE-5/12-D24
ULE-5/12-D24M <SMT>
ULE-5/12-D48
ULE-5/12-D48M <SMT>
ULE-12/4.2-D24, -D48
ULE-12/4.2-D24M <SMT>
ULE-24/3-D48
ULE-48/1.25-D48
ULE-48/1.25-D48M <SMT>
ULE-68/1.5-D48
Pin
1
2
3
4
5
6
7
8
Height (Max.)*
0.404 (10.26)
0.404 (10.26)
0.405 (10.29)
0.400 (10.16)
0.405 (10.29)
0.400 (10.16)
0.377 (9.58)
0.400 (10.16)
0.377 (9.58)
0.400 (10.16)
0.425 (10.8)
0.448 (11.38)
0.446 (11.33)
0.377 (9.58)
Function P32
−Input
On/Off Control*
+Input
−Output
−Sense**
Output Trim
+Sense**
+Output
* The Remote On/Off can be provided
with either positive (P suffix) or negative
(N suffix) polarity.
** 12V or greater models do not include
sense inputs.
*Dimensions are in inches (mm).
Please refer to pg. 2 for complete model numbers.
Case C52 Surface-Mount Package
Case C56 Through-Hole Package
2.30 (58.4)
PINS 1-3, 5-7:
0.040 ±0.001 (1.016 ±0.025)
PINS 4, 8:
0.062 ±0.001 (1.575 ±0.025)
2.30 (58.4)
COPPER SMT LEADS
COPLANAR TO 0.004
0.025
(0.6)
(Nylon Spacers)
(for nylon spacer models)
2.00 (50.80)
0.125 TYP. (3.2)
A
B
B
B
A
A
0.210 ±0.015
(5.3 ±0.4)
See
table
A
A
See
table
4
1
1
5
4
0.600
(15.2)
5
0.600
(15.2)
6
2
0.90
(22.9)
8
BOTTOM VIEW
0.300
(7.6)
3
0.300
(7.6)
8
0.600 (15.2)
4 EQ. SP. @
0.150 (3.8)
0.90
(22.9)
7
7
3
6
2
BOTTOM VIEW
0.600 (15.2)
4 EQ. SP. @
0.150 (3.8)
0.110 TYP.
(2.8)
Please refer to the Pin Change discussion on page 6.
Dimensions are in inches (mm shown for ref. only).
Third Angle Projection
Tolerances (unless otherwise specified):
.XX ± 0.02 (0.5)
.XXX ± 0.010 (0.25)
Angles ± 2˚
Components are shown for reference only.
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MDC_ULE Series.C11 Page 7 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Absolute Maximum Ratings
Input Voltage:
Continuous:
12 Volt input models
24 Volt input models
48 Volt input models
Transient (100 mSec. Max.)
12 Volt input models
24 Volt input models
48 Volt input models
18 Volts
36 Volts
75 Volts
25 Volts
50 Volts
100 Volts
On/Off Control (pin 2)
See specifications
Input Reverse Polarity Protection
5 Amps, 10 sec. max.
Output Overvoltage Protection
Magnetic feedback. See note (7).
Output Current *
Current-limited. Devices can with stand
sustained short circuit without damage.
Storage Temperature
–55 to +125°C.
Lead Temperature
Refer to solder profile.
These are stress ratings. Exposure of devices to greater than any of these conditions
may adversely affect long-term reliability. Proper operation under conditions other than
those listed in the Performance/Functional Specifications Table is not implied.
* The outputs are not intended to sink appreciable current.
TECHNICAL NOTES
Input Fusing
Certain applications and/or safety agencies may require the installation of
fuses at the inputs of power conversion components. Fuses should also be
used if the possibility of sustained, non-current-limited, input-voltage polarity
reversals exist. For MPS ULE 24-60 Watt DC/DC Converters, you should use
slow-blow type fuses, installed in the ungrounded input supply line, with values
no greater than the following.
Model
12 Volt Input
24 Volt input
48 Volt Input
Fuse Values
10 Amps
5 Amps
4 Amps
All relevant national and international safety standards and regulations must
be observed by the installer. For system safety agency approvals, the converters must be installed in compliance with the requirements of the end-use
safety standard, e.g., IEC/EN/UL60950-1.
Input Undervoltage Shutdown and Start-Up Threshold
Under normal start-up conditions, devices will not begin to regulate until
the ramping-up input voltage exceeds the Start-Up Threshold Voltage. Once
operating, devices will not turn off until the input voltage drops below the
Undervoltage Shutdown limit. Subsequent re-start will not occur until the input
is brought back up to the Start-Up Threshold. This built in hysteresis prevents
any unstable on/off situations from occurring at a single input voltage.
Start-Up Time
The VIN to VOUT Start-Up Time is the interval of time between the point at which
the ramping input voltage crosses the Start-Up Threshold and the fully loaded
output voltage enters and remains within its specified accuracy band. Actual
measured times will vary with input source impedance, external input/output
capacitance, and load. The ULE Series implements a soft start circuit that limits
the duty cycle of its PWM controller at power up, thereby limiting the input
inrush current.
The On/Off Control to VOUT start-up time assumes the converter has its
nominal input voltage applied but is turned off via the On/Off Control pin. The
specification defines the interval between the point at which the converter is
turned on and the fully loaded output voltage enters and remains within its
specified accuracy band. Similar to the VIN to VOUT start-up, the On/Off Control
to VOUT start-up time is also governed by the internal soft start circuitry and
external load capacitance.
The difference in start up time from VIN to VOUT and from On/Off Control to
VOUT is therefore insignificant.
Input Source Impedance
ULE converters must be driven from a low ac-impedance input source. The
DC/DC’s performance and stability can be compromised by the use of highly
inductive source impedances. The input circuit shown in Figure 2 is a practical
solution that can be used to minimize the effects of inductance in the input
traces. For optimum performance, components should be mounted close to
the DC/DC converter. If the application has a high source impedance, low VIN
models can benefit of increased external input capacitance.
I/O Filtering, Input Ripple Current, and Output Noise
All models in the ULE 24-60 Watt DC/DC Converters are tested/specified for
input reflected ripple current and output noise using the specified external input/
output components/circuits and layout as shown in the following two figures.
External input capacitors (CIN in Figure 2) serve primarily as energy-storage
elements, minimizing line voltage variations caused by transient IR drops in
conductors from backplane to the DC/DC. Input caps should be selected for bulk
capacitance (at appropriate frequencies), low ESR, and high rms-ripple-current
ratings. The switching nature of DC/DC converters requires that dc voltage
sources have low ac impedance as highly inductive source impedance can affect
system stability. In Figure 2, CBUS and LBUS simulate a typical dc voltage bus. Your
specific system configuration may necessitate additional considerations.
TO
OSCILLOSCOPE
CURRENT
PROBE
+
VIN
+INPUT
LBUS
CBUS
CIN
–
–INPUT
CIN = 33μF, ESR < 700mΩ @ 100kHz
CBUS = 220μF, ESR < 100mΩ @ 100kHz
LBUS = 12μH
Figure 2. Measuring Input Ripple Current
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MDC_ULE Series.C11 Page 8 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
In critical applications, output ripple/noise (also referred to as periodic and
random deviations or PARD) may be reduced below specified limits using filtering techniques, the simplest of which is the installation of additional external
output capacitors. These output caps function as true filter elements and
should be selected for bulk capacitance, low ESR and appropriate frequency
response. All external capacitors should have appropriate voltage ratings and
be located as close to the converter as possible. Temperature variations for all
relevant parameters should also be taken carefully into consideration. The most
effective combination of external I/O capacitors will be a function of line voltage and source impedance, as well as particular load and layout conditions.
In Figure 3, the two copper strips simulate real-world pcb impedances
between the power supply and its load. In order to minimize measurement
errors, scope measurements should be made using BNC connectors, or the
probe ground should be less than ½ inch and soldered directly to the fixture.
rise above the designed operating temperature, a precision temperature sensor
will power down the unit. When the internal temperature decreases below the
threshold of the temperature sensor, the unit will self start. See Performance/
Functional Specifications.
Output Overvoltage Protection
ULE output voltages are monitored for an overvoltage condition via magnetic
feedback. The signal is coupled to the primary side and if the output voltage
rises to a level which could be damaging to the load, the sensing circuitry will
power down the PWM controller causing the output voltages to decrease. Following a time-out period the PWM will restart, causing the output voltages to
ramp to their appropriate values. If the fault condition persists, and the output
voltages again climb to excessive levels, the overvoltage circuitry will initiate
another shutdown cycle. This on/off cycling is referred to as "hiccup" mode.
Contact MPS for an optional output overvoltage monitor circuit using a
comparator which is optically coupled to the primary side thus allowing tighter
and more precise control.
+SENSE
COPPER STRIP
+OUTPUT
C1
C2
SCOPE
RLOAD
–OUTPUT
–SENSE
Current Limiting
As soon as the output current increases to 10% to 50% above its rated value,
the DC/DC converter will go into a current-limiting mode. In this condition, the
output voltage will decrease proportionately with increases in output current,
thereby maintaining somewhat constant power dissipation. This is commonly
referred to as power limiting. Current limit inception is defined as the point at
which the full-power output voltage falls below the specified tolerance. See
Performance/Functional Specifications. If the load current, being drawn from
the converter, is significant enough, the unit will go into a short circuit condition
as specified under "Performance."
COPPER STRIP
C1 = 0.47μF CERAMIC
C2 = NA
LOAD 2-3 INCHES (51-76mm) FROM MODULE
Figure 3. Measuring Output Ripple/Noise (PARD)
Floating Outputs
Since these are isolated DC/DC converters, their outputs are "floating" with
respect to their input. Designers will normally use the –Output (pin 4) as the
ground/return of the load circuit. You can, however, use the +Output (pin 8) as
ground/return to effectively reverse the output polarity.
Minimum Output Loading Requirements
ULE converters employ a synchronous-rectifier design topology and all models
regulate within spec and are stable under no-load to full load conditions.
Operation under no-load conditions however might slightly increase the output
ripple and noise.
Thermal Shutdown
These ULE converters are equipped with thermal-shutdown circuitry. If environmental conditions cause the internal temperature of the DC/DC converter to
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Short Circuit Condition
When a converter is in current-limit mode, the output voltage will drop as
the output current demand increases. If the output voltage drops too low, the
magnetically coupled voltage used to develop primary side voltages will also
drop, thereby shutting down the PWM controller. Following a time-out period,
the PWM will restart causing the output voltages to begin ramping to their
appropriate values. If the short-circuit condition persists, another shutdown
cycle will be initiated. This on/off cycling is referred to as "hiccup" mode. The
hiccup cycling reduces the average output current, thereby preventing internal
temperatures from rising to excessive levels. The ULE is capable of enduring an
indefinite short circuit output condition.
Features and Options
On/Off Control
The input-side, remote On/Off Control function can be ordered to operate with
either polarity:
Standard models are equipped with Positive-polarity (“P" part-number
suffix) and these devices are enabled when the On/Off Control is left open or
is pulled high, as per Figure 4. Positive-polarity devices are disabled when the
On/Off Control is pulled low.
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MDC_ULE Series.C11 Page 9 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
+ Vcc
+OUTPUT
–INPUT
ON/OFF CONTROL
+SENSE
CONTROL
ON/OFF
CONTROL
20kΩ
5-20
TURNS
TRIM
LOAD
–SENSE
-INPUT
+INPUT
Figure 4. Driving the Positive Polarity On/Off Control Pin
Optional Negative-polarity devices (“N” suffix) are off when the On/Off Control
is open (or pulled high), and on when the On/Off Control is pulled low with
respect to –VIN as shown in Figure 5.
).054
–OUTPUT
Figure 6. Trim Connections Using A Trimpot
–INPUT
+OUTPUT
+SENSE
ON/OFF
CONTROL
TRIM
LOAD
R1
6##
–SENSE
+INPUT
/./&&
#/.42/,
–OUTPUT
Figure 7. Trim Connections To Increase Output Voltages Using a Fixed Resistor
n).054
Figure 5. Driving the Negative Polarity On/Off Control Pin
Dynamic control of the remote on/off function is facilitated with a mechanical
relay or an open-collector/open-drain drive circuit (optically isolated if appropriate). The drive circuit should be able to sink appropriate current (see Performance
Specs) when activated and withstand appropriate voltage when deactivated.
Applying an external voltage to the On/Off Control when no input power is
applied to the converter can cause permanent damage to the converter.
Trimming Output Voltage
ULE converters have a trim capability that allows users to adjust the output
voltages –15% to +10% of VOUT. Adjustments to the output voltages can be
accomplished via a trim pot (Figure 6) or a single fixed resistor as shown in Figures 7 and 8. A single fixed resistor can increase or decrease the output voltage
depending on its connection. The resistor should be located close to the converter and have a TCR less than 100ppm/°C to minimize sensitivity to changes
in temperature. If the trim function is not used, leave the trim pin floating.
–INPUT
+OUTPUT
+SENSE
ON/OFF
CONTROL
TRIM
LOAD
R2
–SENSE
+INPUT
–OUTPUT
Figure 8. Trim Connections To Decrease Output Voltages
A single resistor connected from the Trim to the +Output, or +Sense where
applicable, will increase the output voltage in this configuration. A resistor connected from the Trim to the –Output, or –Sense where applicable, will decrease
the output voltage in this configuration.
Trim adjustments greater than the specified ±5% can have an adverse affect on the converter's performance and are not recommended. Excessive voltage differences between VOUT and Sense, in conjunction with trim adjustment
of the output voltage, can cause the overvoltage protection circuitry to activate
(see Performance Specifications for overvoltage limits). Power derating is
based on maximum output current and voltage at the converter’s output pins.
Use of trim and sense functions can cause output voltages to increase, thereby
increasing output power beyond the converter's specified rating or cause
output voltages to climb into the output overvoltage region. Therefore:
(VOUT at pins) x (IOUT) <= rated output power
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MDC_ULE Series.C11 Page 10 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Remote Sense Note: The Sense and VOUT lines are internally connected
through low value resistors. Nevertheless, if the sense function is not used for
remote regulation the user should connect the +Sense to +VOUT and –Sense to
–VOUT at the DC/DC converter pins.
Trim Equations
Trim Up
Trim Down
3.3 Volt Output
RT UP (kΩ) =
13.3(VO – 1.226)
VO – 3.3
–10.2
RTDOWN (kΩ) =
16.31
3.3 – VO
–10.2
5 Volt Output
RT UP (kΩ) =
20.4(VO – 1.226)
VO – 5
–10.2
RTDOWN (kΩ) =
25.01
5 – VO
–10.2
12 Volt Output
RT UP (kΩ) =
49.6(VO – 1.226)
VO – 12
–10.2
RTDOWN (kΩ) =
60.45
12 – VO
–10.2
101(VO – 1.226)
VO – 24
–10.2
RTDOWN (kΩ) =
124.2
24 – VO
ULE series converters will compensate for drops between the output voltage
at the DC/DC and the sense voltage at the DC/DC provided that:
[VOUT(+) –VOUT(–)] –[Sense(+) –Sense (–)] ≤ 5% VOUT
24 Volt Output
RT UP (kΩ) =
ULE series converters have a sense feature to provide point of use regulation, thereby overcoming moderate IR drops in pcb conductors or cabling.
The remote sense lines carry very little current and therefore require minimal
cross-sectional-area conductors. The sense lines are used by the feedback
control-loop to regulate the output. As such, they are not low impedance points
and must be treated with care in layouts and cabling. Sense lines on a pcb
should be run adjacent to dc signals, preferably ground. In cables and discrete
wiring applications, twisted pair or other techniques should be implemented.
–10.2
Note: Resistor values are in kΩ. Adjustment accuracy is subject to resistor
tolerances and factory-adjusted output accuracy. VO = desired output voltage.
Soldering Guidelines
Murata Power Solutions recommends the specifications below when installing these
converters. These specifications vary depending on the solder type. Exceeding these
specifications may cause damage to the product. Be cautious when there is high
atmospheric humidity. We strongly recommend a mild pre-bake (100 ºC. for 30
minutes). Your production environment may differ therefore please thoroughly review
these guidelines with your process engineers.
Reflow Solder Operations for surface-mount products (SMT)
Output overvoltage protection is monitored at the output voltage pin, not
the Sense pin. Therefore, excessive voltage differences between VOUT and
Sense in conjunction with trim adjustment of the output voltage can cause the
overvoltage protection circuitry to activate (see Performance Specifications
for overvoltage limits). Power derating is based on maximum output current
and voltage at the converter’s output pins. Use of trim and sense functions can
cause output voltages to increase thereby increasing output power beyond the
ULE’s specified rating or cause output voltages to climb into the output overvoltage region. Also, the use of Trim Up and Sense combined may not exceed
+10% of VOUT. Therefore, the designer must ensure:
(VOUT at pins) x (IOUT) ≤ rated output power
Contact and PCB resistance
losses due to IR drops
+OUTPUT
–INPUT
For Sn/Ag/Cu based solders:
IOUT
Preheat Temperature
Less than 1 ºC. per second
Time over Liquidus
45 to 75 seconds
Maximum Peak Temperature
Cooling Rate
+SENSE
Sense Current
ON/OFF
CONTROL
260 ºC.
TRIM
LOAD
Sense Return
Less than 3 ºC. per second
–SENSE
For Sn/Pb based solders:
IOUT Return
Preheat Temperature
Less than 1 ºC. per second
Time over Liquidus
60 to 75 seconds
Maximum Peak Temperature
235 ºC.
Cooling Rate
Less than 3 ºC. per second
+INPUT
–OUTPUT
Contact and PCB resistance
losses due to IR drops
Figure 9. Remote Sense Circuit Configuration
Wave Solder Operations for through-hole mounted products (THMT)
For Sn/Ag/Cu based solders:
Maximum Preheat Temperature
115° C.
Maximum Pot Temperature
270° C.
Maximum Solder Dwell Time
7 seconds
For Sn/Pb based solders:
Maximum Preheat Temperature
105° C.
Maximum Pot Temperature
250° C.
Maximum Solder Dwell Time
6 seconds
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MDC_ULE Series.C11 Page 11 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Typical Performance Curves
ULE-1.5/20-D48 Maximum Current Temperature Derating
(VIN = 48V, air flow direction is transverse)
ULE-1.5/20-D48N
Efficiency vs. Line Voltage and Load Current @ +25°C
25
90
88
20
86
Output Current (Amps)
Efficiency (%)
84
82
80
VIN = 36V
78
VIN = 48V
76
100 lfm
15
200 lfm
300 lfm
10
400 lfm
VIN = 75V
74
5
72
70
2
4
6
8
10
12
14
16
18
0
–40
20
0
25
30
35
Load Current (Amps)
40
50
45
55
60
65
70
75
80
85
Ambient Temperature (°C)
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85
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ULE-2.5/20-D24N
Efficiency vs. Line Voltage and Load Current @ +25°C
ULE-2.5/20-D24N Maximum Current Temperature Derating
VIN = 24V, transverse air flow at sea level
92
20
90
19.5
88
19
Output Current (Amps)
Efficiency (%)
86
84
VIN = 19V
82
VIN = 24V
80
VIN = 36V
Natural convection
100 lfm
200 lfm
300 lfm
400 lfm
18.5
18
17.5
78
17
76
74
16.5
2
4
6
8
10
12
14
16
18
20
Load Current (Amps)
20
25
30
35
40
45
50
55
60
65
70
Ambient Temperature (°C)
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MDC_ULE Series.C11 Page 12 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Typical Performance Curves
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MDC_ULE Series.C11 Page 13 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Typical Performance Curves
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Efficiency vs. Line Voltage and Load Current @ +25°C
94
92
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90
Efficiency (%)
88
86
VIN = 9V
84
VIN = 12V
.ATURALCONVECTION
LFM
LFM
82
VIN = 18V
LFM
80
78
1.2
2.4
3.6
4.8
6
7.2
8.4
9.6
10.8
12
n
!MBIENT4EMPERATUREo#
Load Current (Amps)
5,%$-AXIMUM#URRENT4EMPERATURE$ERATING
6).6AIRFLOWDIRECTIONFROMINPUTTOOUTPUT
5,%$
%FFICIENCYVS,INE6OLTAGEAND,OAD#URRENT —#
/UTPUT#URRENT!MPS
%FFICIENCY
6).6
6).6
LFM
LFM
LFM
6).6
n
!MBIENT4EMPERATUREo#
,OAD#URRENT!MPS
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MDC_ULE Series.C11 Page 14 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Typical Performance Curves
5,%$
%FFICIENCYVS,INE6OLTAGEAND,OAD#URRENT —#
ULE-5/12-D48 Maximum Current Temperature Derating
(VIN = 48V, air flow direction from input to output)
12.5
12
%FFICIENCY
Output Current (Amps)
11.5
6).6
6).6
6).6
11
10.5
100 lfm
10
200 lfm
9.5
9
300 lfm
8.5
8
–40
0
30
35
40
94
4.2
92
4.1
55
60
65
70
75
80
85
90
70
75
80
85
90
70
75
80
85
90
4.0
90
3.9
Output Current (Amps)
88
Efficiency (%)
50
ULE-12/4.2-D24N Maximum Current Temperature Derating
(VIN=24V, transverse airflow at sea level)
ULE-12/4.2-D24
Efficiency Vs. Line Voltage and Load Current @25ºC
86
VIN = 18V
VIN = 24V
VIN = 26V
84
82
Natural convection
100 lfm
200 lfm
300 lfm
400 lfm
3.8
3.7
3.6
3.5
80
3.4
78
3.3
76
0.20
3.2
0.60
1.00
1.40
1.80
2.20
2.60
3.00
3.40
3.80
20
4.20
25
30
35
40
5,%$
%FFICIENCYVS,INE6OLTAGEAND,OAD#URRENT —#
50
55
60
65
ULE-12/4.2-D48N Maximum Current Temperature Derating
(VIN=48V, transverse airflow at sea level)
4.5
4.0
3.5
Output Current (Amps)
6).6
6).6
3.0
Natural convection
100 lfm
200 lfm
300 lfm
400 lfm
2.5
2.0
1.5
1.0
6).6
0.5
45
Ambient Temperature (°C)
Load Current (Amps)
%FFICIENCY
45
Ambient Temperature (oC)
,OAD#URRENT!MPS
0
20
25
30
35
40
45
50
55
60
65
Ambient Temperature (°C)
,OAD#URRENT!MPS
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MDC_ULE Series.C11 Page 15 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Typical Performance Curves
ULE-24/3-D48
Efficiency vs. Line Voltage and Load Current @ +25°C
ULE-48/1.5-D48
Efficiency vs. Line Voltage and Load Current @ +25°C
93
92
90
91
88
90
86
Efficiency (%)
Efficiency (%)
92
89
88
VIN = 36V
VIN = 48V
87
VIN = 60V
VIN = 75V
84
82
VIN = 36V
VIN = 48V
80
VIN = 60V
VIN = 75V
78
76
86
74
85
72
84
0.3
0.65
1
1.3
1.65
2
2.3
2.65
70
0.10
3
0.22
0.33
0.45
0.56
5,%$0OWER$ISSIPATIONVS,OAD#URRENT —#
0.91
1.02
1.14
1.25
6).6
0OWER$ISSIPATION7ATTS
0OWER$ISSIPATION7ATTS
0.79
5,%$0OWER$ISSIPATIONVS,OAD#URRENT —#
6).6
6).6
6).6
6).6
6).6
,OAD#URRENT!MPS
5,%$0OWER$ISSIPATIONVS,OAD#URRENT —#
0OWER$ISSIPATION7ATTS
6).6
6).6
6).6
6).6
6).6
6).6
,OAD#URRENT!MPS
5,%$0OWER$ISSIPATIONVS,OAD#URRENT —#
0OWER$ISSIPATION7ATTS
0.68
Load Current (Amps)
Load Current (Amps)
,OAD#URRENT!MPS
,OAD#URRENT!MPS
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MDC_ULE Series.C11 Page 16 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Typical Performance Curves
5,%$0OWER$ISSIPATIONVS,OAD#URRENT —#
5,%$0OWER$ISSIPATIONVS,OAD#URRENT —#
6).6
0OWER$ISSIPATION7ATTS
0OWER$ISSIPATION7ATTS
6).6
6).6
6).6
6).6
6).6
,OAD#URRENT!MPS
,OAD#URRENT!MPS
5,%$0OWER$ISSIPATIONVS,OAD#URRENT —#
5,%$0OWER$ISSIPATIONVS,OAD#URRENT —#
6).6
6).6
6).6
0OWER$ISSIPATION7ATTS
0OWER$ISSIPATION7ATTS
6).6
6).6
6).6
,OAD#URRENT!MPS
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,OAD#URRENT!MPS
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MDC_ULE Series.C11 Page 17 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Typical Performance Curves
5,%$0OWER$ISSIPATIONVS,OAD#URRENT —#
ULE-24/3-D48 Power Dissipation vs. Load Current @ +25°C
6.5
6
VIN = 75V
VIN = 60V
VIN = 48V
VIN = 36V
5
6).6
Power Dissipation (Watts)
0OWER$ISSIPATION7ATTS
5.5
6).6
6).6
4.5
4
3.5
3
2.5
2
1.5
,OAD#URRENT!MPS
1
0.3
0.65
1
1.3
1.65
2
2.3
2.65
3
Load Current (Amps)
ULE-48/1.5-D48 Power Dissipation vs. Load Current @ +25°C
7
Power Dissipation (Watts)
6
VIN = 75V
VIN = 60V
VIN = 48V
VIN = 36V
5
4
3
2
1
0.1
0.2
0.3
0.4
0.6
0.7
0.8
0.9
1.0
1.1
1.3
Load Current (Amps)
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MDC_ULE Series.C11 Page 18 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
ULE Block Diagrams
The ULE series consist of a number of unique high performance designs
sharing similar mechanical outlines and pinouts. The internal architecture
uses several different topologies including push-pull, flyback and others.
The block diagrams below are typical examples and are not intended to be
exact representations. Please be aware that MPS may change these designs
as needed.
ULE-3.3/20-D48N
+SENSE
+VOUT
+VIN
GATE
DRIVE
FEEDBACK
–VIN
−VOUT
−SENSE
PWM
CONTROLLER
ON/OFF
CONTROL
UV, OV AND
OVER-TEMPERATURE
COMPARATORS
OPTO
ISOLATION
REFERENCE &
ERROR AMP
TRIM
Typical topology is shown.
ULE-12/4.2-D48N
+VIN
+VOUT
–VIN
ON/OFF
CONTROL
−VOUT
FEEDBACK
PWM
CONTROLLER
UV, OV AND
OVER-TEMPERATURE
COMPARATORS
REFERENCE &
ERROR AMP
Typical topology is shown.
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MDC_ULE Series.C11 Page 19 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Simplified Block Diagrams (continued)
ULE-24/2-D48N
+VIN
–VIN
ON/OFF
CONTROL
FEEDBACK
+VOUT
PWM
CONTROLLER
−VOUT
UV, OV AND
OVER-TEMPERATURE
COMPARATORS
OPTO
ISOLATION
REFERENCE &
ERROR AMP
TRIM
Typical topology is shown.
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MDC_ULE Series.C11 Page 20 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
Surface-Mount Package ("M" suffix)
MPS’s ULE series SMT DC/DC converters are the only higher-power DC/DCs that
can be automatically “pick-and-placed” using standard vacuum-pickup equipment and subsequently reflowed using high-temperature, lead-free solder.
Virtually all SMT DC/DCs today are unprotected "open-frame" devices assembled by their vendors with high-temperature solder (usually Sn96.5/Ag3.5
with a melting point +221°C) so that you may attach them to your board using
low-temperature solder (usually Sn63/Pb37 with a melting point of +183°C).
Conceptually straightforward, this "stepped" solder approach has its limitations . . . and is clearly out of step with an industry trending toward the broad
use of lead-free solders. Users need to experiment and develop reflow profiles
that ensure the components on their DC/DC never exceed 215-216°C. If those
components get too hot, "double-reflow" could compromise the reliability of
their solder joints. Virtually all these devices demand you "cool down" the Sn63
profile you are likely using today.
MPS is not exempted from the Laws of Physics. And we do not have magic
solders no one else has. We do have a simple and practical, straightforward
approach that works. We assemble our SMT DC/DCs on a thermally-stable
plastic lead-frame (nylon 46, UL94V-0 flammability rated) using a high temperature lead-free solder. The lead-frame ensures coplanarity (to within 0.004 in.)
of the unit's tin-plated (150 microinches) copper leads and also supports a
removable heat shield.
The disposable heat shield, with a cutaway exposing the package leads,
provides thermal insulation to internal components during reflow and doubles as
the vacuum pick-up location. The insulation properties of the heat shield are so
effective that temperature differentials as high as 50°C develop inside-to-outside
the shield. Oven temperature profiles with peaks of 250-260°C and dwell times
exceeding 2 minutes above 221°C are easily achieved. MPS’s new-generation
SMT units are shipped in stackable, JEDEC-style plastic trays (Figure 13).
Mechanical Configuration of Input/Output Connections
These new converters are supplied either using traditional through-hole pins
or SMT leads. (Note that some models are offered only with lead mounting).
The pin options insert into plated-through holes in the host pcb. Be aware that
some heat dissipation is carried off by either the pins or leads. The Derating
Curves assume that some additional pad area is available on your host pcb to
absorb the heat.
The lead option uses either short tabs in "gullwing" style or standoff leads
under the converter. The gullwing leads typically are copper alloy with 150
microinches of tin plating. Solder paste (typically 0.008" to 0.009" thick) is applied to the host pcb using a solder mask pressure screening technique and the
board is heated and cooled long enough for the solder to reflow and adhere to
both the host pads and the converter’s mounting leads.
After such mounting, the entire mechanical mounting load is carried by the
solder. Obviously the converters must be accurately positioned all during the
solder reflow period. Where solder surface tension is sufficient to force tiny
components into position, these larger converters may not move and must be
accurately positioned by your SMT system.
Part Handling and Supply
SMT eighth- and quarter-brick DC/DC converters (plus installed heat shields if
used) are supplied in JEDEC-standard 5.35" by 12.4" waffle trays which are
compatible with the feeders on industry-standard pick-and-place machines.
Since the converters are larger and heavier than many other components,
make sure your system can reliably remove the units from their trays, move
them to the host pcb and accurately position them. The plastic heat shield
(Figure 10) doubles as a vacuum pickup area.
Automated Assembly Production Notes
MPS’s new high-efficiency DC/DC converters are designed for modern surfacemount technology (SMT) automated assembly using screened solder paste,
"pick and place" component positioning and forced hot air reflow oven soldering. If you are new to SMT techniques and have a volume application, these
features save time, cost and improve manufacturing efficiency. MPS’s DC/DC
assembly operations themselves make extensive use of such techniques.
Even if you have previous SMT experience, you should read the sections below on solder reflow profiles and heat shields. This information is not intended
to replace the documentation for your SMT system. We assume that you are
already experienced with all the components of your SMT system.
This section will discuss several SMT issues, including:
Figure 10. ULE SMT DC/DC with Disposable Heat Shield
I/O Mechanical Configuration
Solder Balls
ULE converters are thoroughly inspected according to military standard
J-STD-001B for the presence of solder balls. The specification allows small
solder balls as long as they are rigidly attached and do not compromise the
spacing and clearance requirements needed to maintain electrical isolation.
Part Handling and Supply
Printed Circuit Board (pcb) Mounting
Soldering using Reflow Technology
Temperature Profiling
Heat Shields and Removal
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MDC_ULE Series.C11 Page 21 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
250
Degrees Celsius
200
Heat Shield
Test Board
Air Under Shield
150
100
50
Z1
Z2
100
Z3
Z4
Z5
Z6
200
300
Z7
Seconds
400
500
600
Figure 11. Recommended Solder Profile
(When the Heat-shield temperature exceeds +250°C,
the air within is 50°C cooler)
Post Reflow Procedures
After successful solder reflow, be sure to completely clean and dry your assembled boards using a recommended wash solution and dryer. Failure to remove all
flux may cause long term deterioration of on-board conductors and components.
And, traces of contaminants which are not removed may reduce isolation voltages or risk a safety hazard. Be aware that low remaining concentrations of flux
or other assembly compounds can be very difficult to detect by eye.
Pick and Place pcb Mounting
The main issues here are pad area, orientation, positioning accuracy, vacuum
pickup and coplanarity. MPS recommends that pcb pads to interface with the
DC/DC converter should be sized as shown in the diagram below. The pads
footprint accommodates the positioning accuracy of your SMT equipment and
manufactured tolerances of the DC/DC mounting leads.
On the bottom of the converter, the ULE series include optical fiducial marks
viewable by your SMT imaging system. Observing from the bottom, your SMT
imaging camera should find these marks to identify the converter and verify pin
1. On most pick-and-place systems, during head transit, the imaging system will
automatically fine tune the end mounting position of the converter using image
comparisons from these fiducials or other reference marks you have chosen.
The fiducial marks are placed fairly close together because many imaging
systems have a one inch or less observing area since most SMT parts are considerably smaller than these converters. You may prefer to train your imaging
system to use a corner of the converter or an I/O lead.
The fiducial marks will remain identical within any date code lot of converters.
In the remote possibility that the fiducials may have changed position with a PC
board revision, you should not mix different date lots on any one production assembly session. In addition, to avoid non-recognition or misplacement of the converter, retrain your imaging system at the beginning of each series of assembly
sessions. There may be tiny variations in the absolute position from unit to unit.
Coplanarity: MPS manufactures these converters with very flat mounting leads (see coplanarity specs) however your host pcb must also be flat for
a successful mounting. Be aware of possible warping of the pcb under heat
gradients and/or humidity conditions. The solder paste will tolerate a small
amount of mismatch and will tend to “wet” the entire pad area by capillary
action if the temperatures are correct.
0.020 (0.51)
PCB
Copper Pad
2.340 (59.44)
0.183
(4.65)
1.975 (50.17)
0.300 TYP.
(7.62)
Most pick-and-place automatic assembly systems use a
camera which must be trained to recognize the orientation of
the converter before it is assembled onto the host PC board.
This “training” locates and identifies prominent, dimensionally
stable landmarks such as the board corners or fiducial marks.
If you use a camera above the pcb after placement on the solder paste, do
not rely on the inkjet marking on the heat shield to verify proper orientation.
Use the pin 1 notch instead.
SMT LEAD
SMT UNIT
Orientation: When loaded into JEDEC trays, the converters
are oriented in the same direction. See the diagram below. For
the ULE series, a notch is placed on the top of the case (on the
removal tabs) to indicate the pin 1 position. You should visually
inspect the tray to be sure of this orientation.
0.150 TYP.
(3.81)
0.020 REF.
(0.51)
0.130 TYP.
(3.30)
DIMENSIONS ARE IN INCHES (MM)
Figure 12. Recommended SMT Mounting Pad Dimensions
www.murata-ps.com
Vacuum Pickup: Select the vacuum collet on your SMT placement system
for the weight and size of the DC/DC converter. Note that units with heatsinks
are slightly heavier. Tests at MPS have shown that excellent acceleration
and transit head speed are available for these converters if the collet size is
proper and the vacuum is sufficient. When positioning the vacuum collet, use
the geometric center of the heat shield as the pickup area since the center of
gravity is very close.
Soldering
Reflow technology works well for small parts. However, larger components
such as these DC/DC’s with higher thermal mass may require additional reflow
time (but not enough to disturb smaller parts also being reflowed concurrently
with the DC/DC). When this is combined with higher temperature lead-free solders (or solders with reduced heavy metals), there is increased risk of reheating components inside the DC/DC enough so that they either change positions
(and possibly stop functioning) or the components are damaged by the heat.
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDC_ULE Series.C11 Page 22 of 23
ULE Series
Isolated, High Density, Eighth-Brick
1.25–30 Amp, DC/DC Converters
For these reasons, MPS developed disposable heat shields using high temperature plastic. The DC/DC is installed and reflowed with the shield in place.
After successful reflow and cooling, and before washing, the heat shield should
be removed.
5.35 (135.89)
1.50
(38.1)
1.50
(38.1)
Temperature Profiling
We wish to ramp the temperature up and down to successfully reflow the
solder without heat damage. Each reflow oven, humidity conditions, solder
paste type, oven feed rate, and the number of heat zones all require a different
profile. Therefore you may have to experiment.
PIN 1
DIMPLE
Since these converters are constructed using high temperature solders,
there will be no heat problems on your host pcb using traditional solder with
63% lead and 37% tin with a melting point of +183°C. Device lead temperature must remain below 230°C for less than 75 seconds, assuming that the
heat shield is in place. MPS uses a 216°C melt lead-free tin/silver/copper alloy
to assemble these converters.
There are several lead-free solders suitable for your host pcb depending on
your SMT system and whatever local certification and environmental regulations you must observe. Contact MPS if you need specific advice.
2.875
(73.03)
12.40
(314.96)
Heat Shield
Careful thermocouple testing has shown that the interior of the DC/DC under
the heat shield is tens of degrees cooler than the outside ambient temperature
for typical reflow profiles. This protects internal components and limits the
amount of reflow where it is not desired. The heat shield also includes marking
for product identification and a date/lot code.
2.875
(73.03)
2.875
(73.03)
On ULE models, the heat shield is attached to the converter using molded
plastic pins on the heat shield interior which insert into recessed dimples in
the pinframe. An extra molded pin on the heat shield at the pin 1 location (and
corresponding notch on the pcb) can only be installed one way properly on the
pinframe. If the shield accidentally comes loose, it may be reinstalled by aligning the pins and dimples.
To remove the shield from the converter, after successful mounting and cooling, squeeze the heat shield ears inward toward the converter body and pull the
shield upwards. Discard or recycle the shield. If you are using a flux wash cycle,
remove the heat shield before washing to avoid coming loose inside the washer.
1.032
(26.21)
DIMENSIONS ARE IN INCHES (MM)
Figure 13. Shipping Tray
USA:
Murata Power Solutions, Inc.
11 Cabot Boulevard, Mansfield, MA 02048-1151 U.S.A.
Tel: (508) 339-3000 (800) 233-2765 Fax: (508) 339-6356
www.murata-ps.com email: [email protected] ISO 9001 and 14001 REGISTERED
02/05/09
Murata Power Solutions, Inc. makes no representation that the use of its products in the circuits described herein, or the use of other
technical information contained herein, will not infringe upon existing or future patent rights. The descriptions contained herein do not imply
the granting of licenses to make, use, or sell equipment constructed in accordance therewith. Specifications are subject to change without
notice.
© 2008 Murata Power Solutions, Inc.
www.murata-ps.com
Mansfield (MA), Tel: (508) 339-3000, email: [email protected]
Canada:
Toronto, Tel: (866) 740-1232, email: [email protected]
UK:
Milton Keynes, Tel: +44 (0)1908 615232, email: [email protected]
France:
Montigny Le Bretonneux, Tel: +33 (0)1 34 60 01 01, email: [email protected]
Germany:
München, Tel: +49 (0)89-544334-0, email: [email protected]
Japan:
Tokyo, Tel: 3-3779-1031, email: [email protected]
Osaka, Tel: 6-6354-2025, email: [email protected]
China:
Shanghai, Tel: +86 215 027 3678, email: [email protected]
Guangzhou, Tel: +86 208 221 8066, email: [email protected]
Singapore:
Parkway Centre, Tel: +65 6348 9096, email: [email protected]
Technical enquiries email: [email protected], tel: +1 508 339 3000
MDC_ULE Series.C11 Page 23 of 23