Delta DNS12S0A0R10NFC Delphi dnm, non-isolated point of load dc/dc power modules: 2.8-5.5vin, 0.75-3.3v/10a out Datasheet

FEATURES
High efficiency: 96% @ 5.0Vin, 3.3V/10A out
Small size and low profile: (SIP)
50.8x 13.4x 8.0 mm (2.00” x 0.53” x 0.31”)
Signle-in-line (SIP) packaging
Standard footprint
Voltage and resistor-based trim
Pre-bias startup
Output voltage tracking
No minimum load required
Output voltage programmable from
0.75Vdc to 3.3Vdc via external resistor
Fixed frequency operation
Input UVLO, output OTP, OCP
Remote ON/OFF
Remote sense
ISO 9001, TL 9000, ISO 14001, QS9000,
OHSAS18001 certified manufacturing facility
UL/cUL 60950 (US & Canada) Recognized,
and TUV (EN60950) Certified
CE mark meets 73/23/EEC and 93/68/EEC
Delphi DNM, Non-Isolated Point of Load
directives
DC/DC Power Modules: 2.8-5.5Vin, 0.75-3.3V/10A out
OPTIONS
The Delphi Series DNM04, 2.8-5.5V input, single output, non-isolated
Point of Load DC/DC converters are the latest offering from a world
leader in power system and technology and manufacturing -- Delta
Electronics, Inc. The DNM04 series provides a programmable output
voltage from 0.75V to 3.3V using an external resistor. The DNM series
has flexible and programmable tracking and sequencing features to
enable a variety of startup voltages as well as sequencing and tracking
between power modules. This product family is available in a surface
mount or SIP package and provides up to 10A of current in an industry
standard footprint. With creative design technology and optimization of
component placement, these converters possess outstanding electrical
and thermal performance and extremely high reliability under highly
stressful operating conditions.
Negative On/Off logic
Tracking feature
SMD package
APPLICATIONS
Telecom/DataCom
Distributed power architectures
Servers and workstations
LAN/WAN applications
Data processing applications
DATASHEET
DS_DNM04SIP10_05292006
Delta Electronics, Inc.
TECHNICAL SPECIFICATIONS
(TA = 25°C, airflow rate = 300 LFM, Vin = 2.8Vdc and 5.5Vdc, nominal Vout unless otherwise noted.)
PARAMETER
NOTES and CONDITIONS
DNM04S0A0R10PFA
Min.
ABSOLUTE MAXIMUM RATINGS
Input Voltage (Continuous)
Tracking Voltage
Operating Temperature
Storage Temperature
INPUT CHARACTERISTICS
Operating Input Voltage
Input Under-Voltage Lockout
Turn-On Voltage Threshold
Turn-Off Voltage Threshold
Maximum Input Current
No-Load Input Current
Off Converter Input Current
Inrush Transient
Recommended Inout Fuse
OUTPUT CHARACTERISTICS
Output Voltage Set Point
Output Voltage Adjustable Range
Output Voltage Regulation
Over Line
Over Load
Over Temperature
Total Output Voltage Range
Output Voltage Ripple and Noise
Peak-to-Peak
RMS
Output Current Range
Output Voltage Over-shoot at Start-up
Output DC Current-Limit Inception
Output Short-Circuit Current (Hiccup Mode)
DYNAMIC CHARACTERISTICS
Dynamic Load Response
Positive Step Change in Output Current
Negative Step Change in Output Current
Setting Time to 10% of Peak Devitation
Turn-On Transient
Start-Up Time, From On/Off Control
Start-Up Time, From Input
Output Voltage Rise Time
Maximum Output Startup Capacitive Load
EFFICIENCY
Vo=3.3V
Vo=2.5V
Vo=1.8V
Vo=1.5V
Vo=1.2V
Vo=0.75V
FEATURE CHARACTERISTICS
Switching Frequency
ON/OFF Control, (Negative logic)
Logic Low Voltage
Logic High Voltage
Logic Low Current
Logic High Current
ON/OFF Control, (Positive Logic)
Logic High Voltage
Logic Low Voltage
Logic Low Current
Logic High Current
Tracking Slew Rate Capability
Tracking Delay Time
Tracking Accuracy
Remote Sense Range
GENERAL SPECIFICATIONS
MTBF
Weight
Over-Temperature Shutdown
DS_DNM04SIP10_05292006
Typ.
Max.
0
Units
Refer to Figure 45 for measuring point
-40
-55
5.8
Vin,max
+125
+125
Vout ≦ Vin –0.5
2.8
5.5
V
10
100
30
0.1
15
V
V
A
mA
mA
A 2S
A
+2.0
3.63
% Vo,set
V
+3.0
% Vo,set
% Vo,set
% Vo,set
% Vo,set
2.2
2.0
Vin=2.8V to 5.5V, Io=Io,max
70
20
Vin=2.8V to 5.5V, Io=Io,min to Io,max
Vin=5V, Io=100% Io, max, Tc=25℃
Vin=2.8V to 5.5V
Io=Io,min to Io,max
Tc=-40℃ to 100℃
Over sample load, line and temperature
5Hz to 20MHz bandwidth
Full Load, 1µF ceramic, 10µF tantalum
Full Load, 1µF ceramic, 10µF tantalum
-2.0
0.7525
Vo,set
0.3
0.4
0.8
-3.0
25
8
50
15
10
5
280
mV
mV
A
% Vo,set
% Io
Adc
200
200
25
300
300
mV
mV
µs
4
4
4
6
6
8
1000
5000
ms
ms
ms
µF
µF
0
220
3.5
Io,s/c
10µF Tan & 1µF Ceramic load cap, 2.5A/µs
50% Io, max to 100% Io, max
100% Io, max to 50% Io, max
Io=Io.max
Vin=Vin,min, Vo=10% of Vo,set
Vo=10% of Vo,set
Time for Vo to rise from 10% to 90% of Vo,set
Full load; ESR ≧1mΩ
Full load; ESR ≧10mΩ
Vi=5V, 100% Load
Vi=5V, 100% Load
Vi=5V, 100% Load
Vi=5V, 100% Load
Vi=5V, 100% Load
Vi=5V, 100% Load
Module On, Von/off
Module Off, Von/off
Module On, Ion/off
Module Off, Ion/off
Module On, Von/off
Module Off, Von/off
Module On, Ion/off
Module Off, Ion/off
Delay from Vin.min to application of tracking voltage
Power-up
2V/mS
Power-down 1V/mS
Io=100% of Io, max; Ta=25°C
Refer to Figure 45 for measuring point
Vdc
Vdc
°C
°C
96.0
94.2
92.4
91.4
90.0
86.3
%
%
%
%
%
%
300
kHz
-0.2
1.5
0.2
-0.2
0.2
0.1
10
100
200
21.91
10
130
0.3
Vin,max
10
1
V
V
µA
mA
Vin,max
0.3
1
10
2
V
V
mA
µA
V/msec
ms
mV
mV
V
200
400
0.1
M hours
grams
°C
2
100
100
95
95
90
EFFICIENCY(%)
EFFICIENCY(%)
ELECTRICAL CHARACTERISTICS CURVES
Vin=4.5V
Vin=5.0V
85
Vin=5.5V
80
90
Vin=3.0V
85
Vin=5.0
Vin=5.5V
80
75
1
2
3
4
5
6
7
8
9
75
10
1
2
3
OUTPUR CURRENT(A)
95
95
EFFICIENCY(%)
EFFICIENCY(%)
100
Vin=2.8V
Vin=5.0V
Vin=5.5V
80
7
8
9
10
90
Vin=2.8V
85
Vin=5.0
80
75
Vin=5.5V
75
1
2
3
4
5
6
7
8
9
10
1
2
3
OUTPUR CURRENT(A)
5
6
7
8
9
10
Figure 4: Converter efficiency vs. output current (1.5V out)
95
90
90
EFFICIENCY(%)
95
85
80
4
OUTPUR CURRENT(A)
Figure 3: Converter efficiency vs. output current (1.8V out)
EFFICIENCY(%)
6
Figure 2: Converter efficiency vs. output current (2.5V out)
100
85
5
OUTPUR CURRENT(A)
Figure 1: Converter efficiency vs. output current (3.3V out)
90
4
Vin=2.8V
75
Vin=5.0
70
Vin=5.5V
85
80
Vin=2.8V
75
Vin=5.0
70
Vin=5.5V
65
65
60
1
2
3
4
5
6
7
8
9
OUTPUR CURRENT(A)
Figure 5: Converter efficiency vs. output current (1.2V out)
DS_DNM04SIP10_05292006
10
1
2
3
4
5
6
7
8
9
10
OUTPUR CURRENT(A)
Figure 6: Converter efficiency vs. output current (0.75V out)
3
ELECTRICAL CHARACTERISTICS CURVES
Figure 7: Output ripple & noise at 3.3Vin, 2.5V/10A out
Figure 8: Output ripple & noise at 3.3Vin, 1.8V/10A out
Figure 9: Output ripple & noise at 5Vin, 3.3V/10A out
Figure 10: Output ripple & noise at 5Vin, 1.8V/10A out
Figure 11: Turn on delay time at 3.3Vin, 2.5V/10A out
Figure 12: Turn on delay time at 3.3Vin, 1.8V/10A out
DS_DNM04SIP10_05292006
4
ELECTRICAL CHARACTERISTICS CURVES
Figure 13: Turn on delay time at 5Vin, 3.3V/10A out
Figure 14: Turn on delay time at 5Vin, 1.8V/10A out
Figure 15: Turn on delay time at remote turn on 5Vin, 3.3V/16A out
Figure 16: Turn on delay time at remote turn on 3.3Vin, 2.5V/16A
out
Figure 17: Turn on delay time at remote turn on with external
Figure 18: Turn on delay time at remote turn on with external
capacitors (Co= 5000 µF) 5Vin, 3.3V/16A out
capacitors (Co= 5000 µF) 3.3Vin, 2.5V/16A out
DS_DNM04SIP10_05292006
5
ELECTRICAL CHARACTERISTICS CURVES
Figure 19: Typical transient response to step load change at
2.5A/µS from 100% to 50% of Io, max at 5Vin, 3.3Vout
(Cout = 1uF ceramic, 10µF tantalum)
Figure 20: Typical transient response to step load change at
2.5A/µS from 50% to 100% of Io, max at 5Vin, 3.3Vout
(Cout =1uF ceramic, 10µF tantalum)
Figure 21: Typical transient response to step load change at
2.5A/µS from 100% to 50% of Io, max at 5Vin, 1.8Vout
(Cout =1uF ceramic, 10µF tantalum)
Figure 22: Typical transient response to step load change at
2.5A/µS from 50% to 100% of Io, max at 5Vin, 1.8Vout
(Cout = 1uF ceramic, 10µF tantalum)
DS_DNM04SIP10_05292006
6
ELECTRICAL CHARACTERISTICS CURVES
Figure 23: Typical transient response to step load change at
2.5A/µS from 100% to 50% of Io, max at 3.3Vin,
2.5Vout (Cout =1uF ceramic, 10µF tantalum)
Figure 24: Typical transient response to step load change at
2.5A/µS from 50% to 100% of Io, max at 3.3Vin,
2.5Vout (Cout =1uF ceramic, 10µF tantalum)
Figure 25: Typical transient response to step load change at
2.5A/µS from 100% to 50% of Io, max at 3.3Vin,
1.8Vout (Cout =1uF ceramic, 10µF tantalum)
Figure 26: Typical transient response to step load change at
2.5A/µS from 50% to 100% of Io, max at 3.3Vin,
1.8Vout (Cout = 1uF ceramic, 10µF tantalum)
Figure 27: Output short circuit current 5Vin, 0.75Vout
Figure 28:Turn on with Prebias 5Vin, 3.3V/0A out, Vbias =1.0Vdc
DS_DNM04SIP10_05292006
7
TEST CONFIGURATIONS
DESIGN CONSIDERATIONS
Input Source Impedance
TO OSCILLOSCOPE
L
VI(+)
2 100uF
Tantalum
BATTERY
VI(-)
Note: Input reflected-ripple current is measured with a
simulated source inductance. Current is measured at
the input of the module.
Figure 29: Input reflected-ripple test setup
To maintain low noise and ripple at the input voltage, it is
critical to use low ESR capacitors at the input to the
module. Figure 32 shows the input ripple voltage (mVp-p)
for various output models using 200 µF(2 x100uF) low
ESR tantalum capacitor (KEMET p/n: T491D107M016AS,
AVX p/n: TAJD107M106R, or equivalent) in parallel with
47 µF ceramic capacitor (TDK p/n:C5750X7R1C476M or
equivalent). Figure 33 shows much lower input voltage
ripple when input capacitance is increased to 400 µF (4 x
100 µF) tantalum capacitors in parallel with 94 µF (2 x 47
µF) ceramic capacitor.
COPPER STRIP
The input capacitance should be able to handle an AC
ripple current of at least:
Vo
1uF
10uF
SCOPE
tantalum ceramic
Resistive
Load
Irms = Iout
Note: Use a 10µF tantalum and 1µF capacitor. Scope
measurement should be made using a BNC cable.
Figure 30: Peak-peak output noise and startup transient
measurement test setup.
CONTACT AND
DISTRIBUTION LOSSES
VI
Vo
Vo
Vin
Arms
350
300
250
200
150
100
5.0Vin
50
3.3Vin
0
0
Io
II
SUPPLY
Input Ripple Voltage (mVp-p)
GND
Vout ⎛ Vout ⎞
⎜1 −
⎟
Vin ⎝
Vin ⎠
1
2
3
4
Output Voltage (Vdc)
LOAD
GND
Figure 31: Output voltage and efficiency measurement test
setup
Note: All measurements are taken at the module
terminals. When the module is not soldered (via
socket), place Kelvin connections at module
terminals to avoid measurement errors due to
contact resistance.
η =(
Vo × Io
) × 100 %
Vi × Ii
Figure 32: Input voltage ripple for various output models, IO =
10 A (CIN = 2×100 µF tantalum // 47 µF ceramic)
Input Ripple Voltage (mVp-p)
CONTACT RESISTANCE
200
150
100
50
5.0Vin
3.3Vin
0
0
1
2
3
4
Output Voltage (Vdc)
Figure 33: Input voltage ripple for various output models, IO =
10 A (CIN = 4×100 µF tantalum // 2×47 µF ceramic)
DS_DNM04SIP10_05292006
8
DESIGN CONSIDERATIONS (CON.)
FEATURES DESCRIPTIONS
The power module should be connected to a low
ac-impedance input source. Highly inductive source
impedances can affect the stability of the module. An
input capacitance must be placed close to the modules
input pins to filter ripple current and ensure module
stability in the presence of inductive traces that supply
the input voltage to the module.
Remote On/Off
Safety Considerations
For safety-agency approval the power module must be
installed in compliance with the spacing and separation
requirements of the end-use safety agency standards.
For the converter output to be considered meeting the
requirements of safety extra-low voltage (SELV), the
input must meet SELV requirements. The power
module has extra-low voltage (ELV) outputs when all
inputs are ELV.
The input to these units is to be provided with a
maximum 15A time-delay fuse in the ungrounded lead.
The DNM/DNL series power modules have an On/Off
pin for remote On/Off operation. Both positive and
negative On/Off logic options are available in the
DNM/DNL series power modules.
For positive logic module, connect an open collector
(NPN) transistor or open drain (N channel) MOSFET
between the On/Off pin and the GND pin (see figure 34).
Positive logic On/Off signal turns the module ON during
the logic high and turns the module OFF during the logic
low. When the positive On/Off function is not used, leave
the pin floating or tie to Vin (module will be On).
For negative logic module, the On/Off pin is pulled high
with an external pull-up resistor (see figure 35). Negative
logic On/Off signal turns the module OFF during logic
high and turns the module ON during logic low. If the
negative On/Off function is not used, leave the pin
floating or tie to GND. (module will be On)
Vo
Vin
ION/OFF
RL
On/Off
GND
Figure 34: Positive remote On/Off implementation
Vo
Vin
Rpull-up
ION/OFF
On/Off
RL
GND
Figure 35: Negative remote On/Off implementation
Over-Current Protection
To provide protection in an output over load fault
condition, the unit is equipped with internal over-current
protection. When the over-current protection is
triggered, the unit enters hiccup mode. The units
operate normally once the fault condition is removed.
DS_DNM04SIP10_05292006
9
FEATURES DESCRIPTIONS (CON.)
Vtrim = 0.7 − 0.1698 × (Vo − 0.7525)
Over-Temperature Protection
For example, to program the output voltage of a DNL
module to 3.3 Vdc, Vtrim is calculated as follows
The over-temperature protection consists of circuitry that
provides protection from thermal damage. If the
temperature exceeds the over-temperature threshold the
module will shut down. The module will try to restart after
shutdown. If the over-temperature condition still exists
during restart, the module will shut down again. This
restart trial will continue until the temperature is within
specification
Vtrim = 0.7 − 0.1698 × (3.3 − 0.7525) = 0.267V
Remote Sense
RLoad
TRIM
Rtrim
GND
Figure 37: Circuit configuration for programming output voltage
The DNM/DNL provide Vo remote sensing to achieve
proper regulation at the load points and reduce effects of
distribution losses on output line. In the event of an open
remote sense line, the module shall maintain local sense
regulation through an internal resistor. The module shall
correct for a total of 0.5V of loss. The remote sense line
impedance shall be < 10Ω.
Distribution Losses
Vo
Vo
Vin
using an external resistor
Vo
Vtrim
RLoad
TRIM
GND
+
_
Distribution Losses
Figure 38: Circuit Configuration for programming output voltage
using external voltage source
Sense
RL
GND
Distribution
Distribution
L
Figure 36: Effective circuit configuration for remote sense
operation
Output Voltage Programming
The output voltage of the DNM/DNL can be programmed
to any voltage between 0.75Vdc and 3.3Vdc by
connecting one resistor (shown as Rtrim in Figure 37)
between the TRIM and GND pins of the module. Without
this external resistor, the output voltage of the module is
0.7525 Vdc. To calculate the value of the resistor Rtrim
for a particular output voltage Vo, please use the
following equation:
⎡ 21070
⎤
Rtrim = ⎢
− 5110⎥ Ω
⎣Vo − 0.7525
⎦
For example, to program the output voltage of the DNL
module to 1.8Vdc, Rtrim is calculated as follows:
⎡ 21070
⎤
Rtrim = ⎢
− 5110⎥ Ω = 15KΩ
⎣1.8 − 0.7525
⎦
DNL can also be programmed by apply a voltage
between the TRIM and GND pins (Figure 38). The
following equation can be used to determine the value of
Vtrim needed for a desired output voltage Vo:
DS_DNM04SIP10_05292006
Table 1 provides Rtrim values required for some common
output voltages, while Table 2 provides value of external
voltage source, Vtrim, for the same common output
voltages. By using a 1% tolerance trim resistor, set point
tolerance of ±2% can be achieved as specified in the
electrical specification.
Table 1
Vo(V)
Rtrim(KΩ)
0.7525
Open
1.2
41.97
1.5
23.08
1.8
15.00
2.5
6.95
3.3
3.16
Table 2
Vo(V)
Vtrim(V)
0.7525
Open
1.2
0.624
1.5
0.573
1.8
0.522
2.5
0.403
3.3
0.267
10
FEATURE DESCRIPTIONS (CON.)
The amount of power delivered by the module is the
voltage at the output terminals multiplied by the output
current. When using the trim feature, the output voltage
of the module can be increased, which at the same
output current would increase the power output of the
module. Care should be taken to ensure that the
maximum output power of the module must not exceed
the maximum rated power (Vo.set x Io.max ≤ P max).
Voltage Margining
Output voltage margining can be implemented in the
DNL modules by connecting a resistor, R margin-up, from
the Trim pin to the ground pin for margining-up the
output voltage and by connecting a resistor, Rmargin-down,
from the Trim pin to the output pin for margining-down.
Figure 39 shows the circuit configuration for output
voltage margining. If unused, leave the trim pin
unconnected. A calculation tool is available from the
evaluation procedure which computes the values of R
margin-up and
Rmargin-down for a specific output voltage and
margin percentage.
The DNL family has 3 different option codes for TRACK
function.
Option code A: the output voltage TRACK
characteristic can be achieved when
the output voltage of PS2 follows the
output voltage of PS1 on a volt-to-volt
basis. (Figure 41)
Option code B: No TRACK function
Option code C: Implementation of advanced power
tracking techniques is based on connecting the power
good signal or selecting proper value for external
resistor R1 (Figure 40 to Figure 43).
PS1
PS2
PS1
PS2
Figure 40: Sequential
Vo
Vin
Rmargin-down
Q1
PS1
PS1
PS2
PS2
On/Off Trim
Rmargin-up
Rtrim
Q2
GND
Figure 41: Simultaneous
Figure 39: Circuit configuration for output voltage margining
Voltage Tracking
The DNM/DNL family was designed for applications that
have output voltage tracking requirements during
power-up and power-down. The devices have a TRACK
pin to implement three types of tracking method:
sequential, ratio-metric and simultaneous. TRACK
simplifies the task of supply voltage tracking in a power
system by enabling modules to track each other, or any
external voltage, during power-up and power-down.
By connecting multiple modules together, customers
can get multiple modules to track their output voltages
to the voltage applied on the TRACK pin.
PS1
PS2
PS1
PS2
-V△
Figure 42: Ratio-metric
PS1
PS1
-V△
PS2
PS2
The DNL family has 3 different option codes for TRACK
function
Figure 43: Ratio-metric
DS_DNM04SIP10_05292006
11
FEATURE DESCRIPTIONS (CON.)
Ratio-Metric
Sequential
Sequential start-up (Figure 40) is implemented by
connecting the power good pin of PS1 to the TRACK pin
of PS2 with a resistor–capacitor (RC) circuit. Suggest to
use 1µF ceramic capacitor and 2KΩ resistor here.
Besides, this configuration requires PS1 to have a power
good function.
PS1
PS2
Vin
Vin
VoPS2
VoPS1
PWRGD
Ratio–metric is implemented by selecting the resistor
values of the voltage divider on the TRACK pin. To simplify
the tracking design, set initial value of R2 equal to 20KΩ at
internal circuit and adjust resistor R1 for the different
tracking method. The circuit diagram of Ratio-Metric is the
same as Simultaneous when VoPS2 tracks the VoPS1.
For Ratio-Metric applications that need the outputs of PS1
and PS2 go to the regulation set point at the same time
(Figure 43), use the following equation (1) to calculate the
value of resistor R1,
TRACK
R
ENABLE
ENABLE
set △V=Voset,PS1–Voset,PS2 and △V will be negative.
C
R1 =
[(Voset ,PS 2 + ∆V ) − Vref ]
* 20KΩ --------------(1)
Vref
Simultaneous
Simultaneous tracking (Figure 41) is implemented by
using a voltage divider around the TRACK pin. The
objective is to minimize the voltage difference between
the power supply outputs during power up and down.
For type A (DNX0A0XXXX A), the simultaneous tracking
can be accomplished by connecting VoPS1 to the TRACK
pin of PS2 where the voltage divider is inside the PS2.
PS2
PS1
Vin
Vin
Note:
1.
Vref =0.4×Voset,PS2
2.
△V is the maximum difference of voltage between
PS1 and PS2 supply voltage.
For Ratio-Metric applications that need the PS2 supply
voltage rises first at power up and falls second at power
down (Figure 42), use the following equation (2) to
calculate the value of resistor R1,
VoPS2
VoPS1
set △V≦0.4×Voset,PS2 and △V will be negative.
TRACK
ENABLE
ENABLE
R1 =
For type C (DNX0A0XXXX C), the simultaneous tracking
can be accomplished by putting R1 equal to 30.1KΩ
through VoPS1 to the TRACK pin of PS2.
PS1
PS2
Vref
* 20 KΩ ------------------(2)
Note:
1.
Vref =0.4×Voset,PS2
△V is defined as the voltage difference between VoPS1 and
VoPS2 when VoPS2 reaches its rated voltage.
Vin
Vin
VoPS2
VoPS1
30.1K
ENABLE
[(Vo set , ps 2 − ∆V ) − Vref ]
R1
TRACK
ENABLE
DS_DNM04SIP10_05292006
R2
To
Tracking
circuit
20K
12
THERMAL CONSIDERATIONS
Thermal management is an important part of the system
design. To ensure proper, reliable operation, sufficient
cooling of the power module is needed over the entire
temperature range of the module. Convection cooling is
usually the dominant mode of heat transfer.
Hence, the choice of equipment to characterize the
thermal performance of the power module is a wind
tunnel.
Thermal Testing Setup
Delta’s DC/DC power modules are characterized in
heated vertical wind tunnels that simulate the thermal
environments encountered in most electronics
equipment. This type of equipment commonly uses
vertically mounted circuit cards in cabinet racks in which
the power modules are mounted.
The following figure shows the wind tunnel
characterization setup. The power module is mounted
on a test PWB and is vertically positioned within the
wind tunnel. The height of this fan duct is constantly kept
at 25.4mm (1’’).
Thermal Derating
Heat can be removed by increasing airflow over the
module. To enhance system reliability, the power
module should always be operated below the maximum
operating temperature. If the temperature exceeds the
maximum module temperature, reliability of the unit may
be affected.
PWB
FACING PWB
MODULE
AIR VELOCITY
AND AMBIENT
TEMPERATURE
MEASURED BELOW
THE MODULE
50.8 (2.0”)
AIR FLOW
12.7 (0.5”)
25.4 (1.0”)
Note: Wind Tunnel Test Setup Figure Dimensions are in millimeters and (Inches)
Figure 44: Wind tunnel test setup
DS_DNM04SIP10_05292006
13
THERMAL CURVES
12
DNM04S0A0R10(Standard) Output Current vs. Ambient Temperature and Air Velocity
@ Vin = 3.3V, Vo = 2.5V (Either Orientation)
Output Current(A)
10
Natural
Convection
8
6
4
2
0
60
Figure 45: Temperature measurement location
* The allowed maximum hot spot temperature is defined at 125℃
12
DNM04S0A0R10(Standard) Output Current vs. Ambient Temperature and Air Velocity
@ Vin = 5V, Vo = 3.3V (Either Orientation)
65
70
75
80
85
Ambient Temperature (℃)
Figure 48: DNM04S0A0R10 (Standard) Output current vs.
ambient temperature and air velocity@Vin=5V, Vo=2.5V(Either
Orientation)
Output Current(A)
12
DNM04S0A0R10(Standard) Output Current vs. Ambient Temperature and Air Velocity
@ Vin = 3.3V, Vo = 0.75V (Either Orientation)
Output Current(A)
10
Natural
Convection
10
Natural
Convection
8
8
6
6
4
4
2
2
0
60
65
70
75
80
85
Ambient Temperature (℃)
Figure 46: DNM04S0A0R10 (Standard) Output current vs.
ambient temperature and air velocity@Vin=5V, Vo=3.3V(Either
Orientation)
12
0
60
65
70
75
80
85
Ambient Temperature (℃)
Figure 49: DNM04S0A0R10 (Standard) Output current vs.
ambient temperature and air velocity@ Vin=5V,
Vo=0.75V(Either Orientation)
DNM04S0A0R10(Standard) Output Current vs. Ambient Temperature and Air Velocity
@ Vin = 5.0V, Vo = 0.75V (Either Orientation)
Output Current(A)
10
Natural
Convection
8
6
4
2
0
60
65
70
75
80
85
Ambient Temperature (℃)
Figure 47: DNM04S0A0R10(Standard) Output current vs.
ambient temperature and air velocity@Vin=5V, Vo=0.75V(Either
Orientation)
DS_DNM04SIP10_05292006
14
MECHANICAL DRAWING
SMD PACKAGE (OPTIONAL)
DS_DNM04SIP10_05292006
SIP PACKAGE
15
PART NUMBERING SYSTEM
DNM
Product
Series
04
S
0A0
R
10
P
Output
Voltage
Package
Type
Output
Current
On/Off logic
0A0 -
R - SIP
10 - 10A
Programmable
S - SMD
Numbers of
Input Voltage
Outputs
DNL - 16A
04 - 2.8~5.5V
DNM - 10A
12 - 9~14V
S - Single
F
N- negative
P- positive
A
Option Code
F- RoHS 6/6
(Lead Free)
DNS - 6A
A - Standard Function:
Sequencing
B - No tracking pin
C - Tracking feature
MODEL LIST
Model Name
Packaging
Input Voltage
Output Voltage
Output Current
Efficiency
5.0Vin, 100% load
DNM04S0A0R10PFA
SIP
2.8 ~ 5.5Vdc
0.75 V~ 3.3Vdc
10A
96.0% (3.3V)
DNM04S0A0S10PFA
SMD
2.8 ~ 5.5Vdc
0.75 V~ 3.3Vdc
10A
96.0% (3.3V)
CONTACT: www.delta.com.tw/dcdc
USA:
Telephone:
East Coast: (888) 335 8201
West Coast: (888) 335 8208
Fax: (978) 656 3964
Email: [email protected]
Europe:
Phone: +41 31 998 53 11
Fax: +41 31 998 53 53
Email: [email protected]
Asia & the rest of world:
Telephone: +886 3 4526107 ext 6220
Fax: +886 3 4513485
Email: [email protected]
WARRANTY
Delta offers a two (2) year limited warranty. Complete warranty information is listed on our web site or is available upon
request from Delta.
Information furnished by Delta is believed to be accurate and reliable. However, no responsibility is assumed by Delta
for its use, nor for any infringements of patents or other rights of third parties, which may result from its use. No license
is granted by implication or otherwise under any patent or patent rights of Delta. Delta reserves the right to revise these
specifications at any time, without notice.
DS_DNM04SIP10_05292006
16