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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
Features: Small size, minimal footprint - SMT/SIP package 10A Output Current (all voltages) High Efficiency: up to 95% High reliability RoHS Compliant Cost efficient open frame design Output voltage programmable by an external resistor. Monotonic Startup with Pre-Bias +'ve Enable Logic and -`ve Enable Logic models available Optional Power Good Signal Sequencing / Tracking Feature
Output Vout (V) 0.75 1.2 1.5 1.8 2.0 2.5 3.3 5.0 Iout (A) 10 10 10 10 10 10 10 10 PARD (mVp-p) Typ. 50 50 50 50 50 50 50 50 Max. 75 75 75 75 75 75 75 75 Regulation Max Line +/-0.2% +/-0.2% +/-0.2% +/-0.2% +/-0.2% +/-0.2% +/-0.2% +/-0.2% Load +/-0.5% +/-0.5% +/-0.5% +/-0.5% +/-0.5% +/-0.5% +/-0.5% +/-0.5%
Input Vin Nom. (V) 12 12 12 12 12 12 12 12
Efficiency Range (V) Iin Typ (A) 0.8 1.2 1.4 1.7 1.8 2.3 3.0 4.4 Full Load Typ. 80% 86% 89% 90% 91% 92% 93% 95%
6.0 - 14 6.0 - 14 6.0 - 14 6.0 - 14 6.0 - 14 6.0 - 14 6.0 - 14 6.5 - 14
Technical enquiries email: sales@murata-ps.com tel: +508 339 3000 ,
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Input Characteristics Input Voltage Operating Range Input Reflected Ripple Current Inrush Current Transient Input Filter Type (external) Input Turn ON Threshold Input Turn OFF Threshold Enable
(Positive enable has 20K pullup) (Negative enable has no internal pullup resistor)
Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
Min 6.0 Typ. 12 200 100 5.0 4.0 open <0.4 <0.4 2 Min -1.5 0 Typ. Vin Max +1.5 10 75 8000 5.0 <2% 23 -0.2 -0.5 +0.2 +0.5 1 Units % A mVp-p F V A % % % Max 14 0.2 Units Vdc mA p-p A2s F V V Vdc Vdc
Notes & Conditions
Minimum 6.5 V input @ 5 volts output
Positive enable: ON Positive enable: OFF Negative enable: ON; open circuit or Negative enable: OFF Notes & Conditions 100% load
Output Characteristics Vout Accuracy Output Loading Output Ripple & Noise @ 20Mhz Bandwidth. Maximum Capacitive Load Vout Trim Range (Nom) Total Accuracy Current Limit Output Line Regulation Output Load Regulation Turn-on Overshoot SC Protection Technique Pre-bias Start-up at output
Low ESR 0.75 Over line/load temperature
Hiccup with auto recovery Unit starts monotonically with prebias Notes & Conditions 50% step, 0.1A/s Settling Time 10% Vo to 90% Vo Vin to Vout and On/Off to Vout Vout rise to monotonic Notes & Conditions Calculated (MIL-HDBK-217F) See thermal derating text Without derating 300LFM See Power derating curve 2"Lx0.327"Wx0.512"H (50.8x8.3x13.0mm) 1.30"Lx0.53"Wx0.366"H (33x13.46x9.3mm) 0.025" (0.64mm) SQUARE 0.063" x0.065" x 0.112" , SQUARE Matte Sn Finish on component Leads UL94V-0 Min Min Typ. Max 100 200 Units mV s KHz ms ms
Dynamic Characteristics Load Transient Operating Frequency Rise Time Start-Up Time
300 3.5 7
General Specifications MTBF Thermal Protection Operating Ambient Temperature Operating Ambient Temperature SIP Dimensions SMT Dimensions SIP Pin Dimensions SMT Block Dimensions Pin and Block Material Flammability Rating
Typ. 919.53 110
Max
-40 -40
50 85
Units KHrs C C C
0.64
mm
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
Standards Compliance
CSA C22.2, No.60950/UL 60950, Third Edition (2000), File UL E165113
Thermal Considerations The power module operates in a variety of thermal environments; however, sufficient cooling should be provided to help ensure reliable operation of the unit. The thermal data presented is based on measurements taken at various airflows. Note that airflow is parallel to the long axis of the module as shown in Figure 1 and derating applies accordingly.
Figure 1. Thermal Tests Set-Up. The temperature at either location should not exceed 110C. Over-temperature shutdown is evaluated at these locations. The output power of the module should not exceed the rated power for the module(Vo,set X Io,max).
Requirements for Cooling
To predict the approximate cooling needed for the module, refer to the Power Derating Curves in Figures 2-17 . These derating curves are approximations of the ambient temperature and airflow required to keep the power module temperature below it's maximum rating. Once the module is assembled in the actual system, the module's temperature should be verified.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
TYPICAL DERATING CURVES SIP/SMT VERSION
SMT10W-12S05A Vo=0.75V Derating Curve NFA010 SMT Derating Curve Vout=0.75V
12 10 Output Current (A) 8 6 4 2 0 30 40 50 60 70 80 90 Ambient Temperature (C) 0LFM 100LFM 200LFM 300LFM
Fig. 2. SMT Power Derating vs Output Current for 12Vin 0.75V Out.
SIP1 0W-1 2S05A Derating Curve Vout=0.75V .0 NFA010 SIP Derating Curve V1 Vout=0.75V 1 2
Output Current (A)
1 0 8 6 4 2 0 30 40 50 60 70 80 90 A mbient T emperature(C ) 0LFM 1 00LFM 200LFM 300LFM
Fig. 3. SIP Power Derating vs Output Current for 12Vin 0.75V Out.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
SMT10W-12S05A Vo=1.2V Derating Curve NFA010 SMT Derating Curve Vout=1.2V
12 10 Output Current (A 8 6 4 2 0 30 40 50 60 70 80 90
0LFM 100LFM 200LFM 300LFM
Ambient Temperature (C)
Fig 4. SMT Power Derating vs Output Current for 12Vin 1.2V Out.
SIP1 0W-1 2S05A Derating Curve V1 Vout=1 .0 NFA010 SIP Derating Curve Vout=1.2V .2V 1 2
Output Current (A)
1 0 8 6 4 2 0 30 40 50 60 70 80 90 A mbient T emperature(C ) 0LFM 1 00LFM 200LFM 300LFM
Fig 5. SIP Power Derating vs Output Current for 12Vin 1.2V Out.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
SMT10W-12S05A Vo=1.5V Derating Curve NFA010 SMT Derating Curve Vout=1.5V
12 10 Output Current (A) 8 6 4 2 0 30 40 50 60 70 80 90 Ambient Temperature (C) 0LFM 100LFM 200LFM 300LFM
Fig 6. SMT Power Derating vs Output Current for 12Vin 1.5V Out.
NFA010 SIP Derating Curve Vout=1.5V
1 2
SIP1 0W-1 2S05A Derating Curve V1 Vout=1 .0 .5V
Output Current (A)
1 0 8 6 4 2 0 30 40 50 60 70 80 90 0LFM 1 00LFM 200LFM 300LFM
A mbient T emperature(C )
Fig 7. SIP Power Derating vs Output Current for 12Vin 1.5V Out.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
SMT10W-12S05A Vo=1.8V Derating Curve NFA010 SMT Derating Curve Vout=1.8V
12 Output Current (A) 10 8 6 4 2 0 30 40 50 60 70 80 90 Ambient Temperature (C) 0LFM 100LFM 200LFM 300LFM
Fig 8. SMT Power Derating vs Output Current for 12Vin 1.8V Out.
SIP1 0W-1 2S05A Derating Curve V1 Vout=1 .0 .8V NFA010 SIP Derating Curve Vout=1.8V 1 2
Output Current (A)
1 0 8 6 4 2 0 30 40 50 60 70 80 90 A mbient T emperature(C ) 0LFM 1 00LFM 200LFM 300LFM
Fig 9. SIP Power Derating vs Output Current for 12Vin 1.8V Out.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
SMT10W-12S05A Vo=2.0V Derating Curve NFA010 SMT Derating Curve Vout=2.0V
12 10 Output Current (A) 8 6 4 2 0 30 40 50 60 70 80 90 Ambient Temperature (C) 0LFM 100LFM 200LFM 300LFM
Fig 10. SMT Power Derating vs Output Current for 12Vin 2.0V Out.
SIP1 0W-1 .0 NFA010 2S05A Derating Curve V1 Vout=2.0V SIP Derating Curve Vout=2.0V 1 2
Output Current (A)
1 0 8 6 4 2 0 30 40 50 60 70 80 90 0LFM 1 00LFM 200LFM 300LFM
A mbient T emperature(C )
Fig 11. SIP Power Derating vs Output Current for 12Vin 2.0V Out.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
SMT10W-12S05A Vo=2.5V Derating Curve NFA010 SMT Derating Curve Vout=2.5V
12 Output Current (A) 10 8 6 4 2 0 30 40 50 60 70 80 90 Ambient Temperature (C) 0LFM 100LFM 200LFM 300LFM
Fig 12. SMT Power Derating vs Output Current for 12Vin 2.5V Out.
SIP1 0W-1 2S05A derating curve V1 Vout=2.5V .0 NFA010 SIP Derating Curve Vout=2.5V 1 2
Output Current (A)
1 0 8 6 4 2 0 30 40 50 Ambient 60 70 80 90 Temperature(oC) 0LFM 1 00LFM 200LFM 300LFM
Fig 13. SIP Power Derating vs Output Current for 12Vin 2.5V Out.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
NFA010 SMT Derating Curve Vout=3.3V
12 Output Current (A) 10 8 6 4 2 0 30 40 50 60 70 80 90 Ambient Temperature (C) 0LFM 100LFM 200LFM 300LFM
SMT10W-12S05A Vo=3.3V Derating Curve
Fig. 14. SMT Power Derating vs Output Current for 12Vin 3.3V Out.
SIP1 0W-1 2S05A Derating Curve V1 Vout=3.3V .2 NFA010 SIP Derating Curve Vout=3.3V 1 2 1 0
Output Current (A)
8 6 4 2 0 30 40 50 Ambient 60 70 80 90 Temperature(oC) 0LFM 1 00LFM 200LFM 300LFM
Fig 15. SIP Power Derating vs Output Current for 12Vin 3.3V Out.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
SMT10W-12S05A Vo=5.0V Derating Curve NFA010 SMT Derating Curve Vout=5.0V
12 Output Current (A 10 8 6 4 2 0 30 40 50 60 70 80 90
0LFM 100LFM 200LFM 300LFM
Ambient Temperature (C)
Fig. 16. SMT Power Derating vs Output Current for 12Vin 5.0V Out
SIP1 0W-1SIP Derating Curve Vout=5.0V NFA010 2S05A Derating Curve V1.0 Vout=5.0V 1 2
Output Current (A)
1 0 8 6 4 2 0 30 40 50 Ambient 60 70 80 90 Temperature(oC) 0LFM 1 00LFM 200LFM 300LFM
Fig 17. SIP Power Derating vs Output Current for 12Vin 5.0V Out.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
TYPICAL EFFICIENCY CURVES FOR VARIOUS VOLTAGE MODELS SIP/SMT VERSION.
NFA010 SMT Efficiency Curve Vout=0.75V SMT10W-12S05A Vo: 0.75V (Eff Vs Io)
95%
Efficiency (%
85%
75%
6V 12V 14V
65%
55% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 18. SMT Efficiency Curves for Vout=075V (25C)
NFA010 SIP Efficiency Curve Vout=0.75V Io) SIP10W-12S05A Vo: 0.75V (Eff Vs
95%
Efficiency (%
85%
75%
6V 12V 14V
65%
55% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 19. SIP Efficiency Curves for Vout=0.75V (25C)
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
NFA010 SMT10W-12S05A Vo: 1.2V (Eff Vs Io) SMT Efficiency Curve Vout=1.2V
95%
Efficiency (%
85%
75%
6V 12V 14V
65%
55% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 20. SMT Efficiency Curves for Vout=1.2V (25C)
NFA010 SIP Efficiency Curve Vout=1.2V Io) SIP10W-12S05A Vo: 1.2V (Eff Vs
100%
90%
Efficiency (%
80% 6V 12V 70% 14V
60% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 21. SIP Efficiency Curves for Vout=1.2V (25C)
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
SMT10W-12S05A Vo: 1.5V (Eff Vs NFA010 SMT Efficiency Curve Vout=1.5V Io)
95%
Efficiency (%
85%
75%
6V 12V 14V
65%
55% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 22. SMT Efficiency Curves for Vout=1.5V (25C)
SIP10W-12S05A Vo: 1.5V (Eff NFA010 SIP Efficiency Curve Vout=1.5V Vs Io)
100% 95%
Efficiency (%
90% 85% 80% 75% 70% 0 1 2 3 4 5 6 7 8 9 10 6V 12V 14V
Current Load (A)
Fig 23. SIP Efficiency Curves for Vout=1.5V (25C)
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
NFA010SMT10W-12S05A Vo: 1.8V (Eff Vs Io) SMT Efficiency Curve Vout=1.8V
95%
Efficiency (%
85%
75%
6V 12V 14V
65%
55% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 24. SMT Efficiency Curves for Vout=1.8V (25C)
NFA010 SIP Efficiency Curve Vout=1.8V SIP10W-12S05A Vo: 1.8V (Eff Vs Io)
100%
95%
Efficiency (%
90%
85% 6V 80% 12V 14V 75%
70% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 25. SIP Efficiency Curves for Vout=1.8V (25C)
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
NFA010 SMT10W-12S05A Vo: 2.0V (Eff Vs Io) SMT Efficiency Curve Vout=2.0V
95%
85%
75%
6V 12V 14V
65%
55% 0 1 2 3 4 5 6 7 8 9 10
Fig 26. SMT Efficiency Curves for Vout=2.0V (25C)
NFA010 SIP10W-12S05A Vo: 2.0V (Eff Vs Io) SIP Efficiency Curve Vout=2.0V
100%
95%
Efficiency (%
90%
85% 6V 80% 12V 14V 75%
70% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 27. SIP Efficiency Curves for Vout=2.0V (25C)
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
SMT10W-12S05A Vo: 2.5V (Eff Vs NFA010 SMT Efficiency Curve Vout=2.5V Io)
95%
85%
75%
6V 12V 14V
65%
55% 0 1 2 3 4 5 6 7 8 9 10
Fig 28. SMT Efficiency Curves for Vout=2.5V (25C)
NFA010 SIP Efficiency Curve Vout=2.5V SIP10W-12S05A Vo: 2.5V (Eff Vs Io)
100%
95%
Efficiency (%
90%
85% 6V 80% 12V 14V 75%
70% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 29. SIP Efficiency Curves for Vout=2.5V (25C)
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
NFA010 SMT Efficiency Curve Vo: 3.3V (Eff Vs Io) SMT10W-12S05A Vout=3.3V
95%
85%
75%
6V 12V 14V
65%
55% 0 1 2 3 4 5 6 7 8 9 10
Fig 30. SMT Efficiency Curves for Vout=3.3V (25C)
NFA010 SIP Efficiency Curve Vout=3.3V SIP10W-12S05A Vo:3.3V (Eff Vs Io)
100%
95%
Efficiency (%
90%
85% 6V 80% 12V 14V 75%
70% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 31. SIP Efficiency Curves for Vout=3.3V (25C)
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
SMT10W-12S05A Curve Vout=5.0V NFA010 SMT EfficiencyVo: 05.0V (Eff Vs Io)
95%
Efficiency (%
85%
75%
6.5V 12V 14V
65%
55% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 32. SMT Efficiency Curves for Vout=5.0V (25C)
NFA010 SIP Efficiency Curve Vout=5.0V SIP10W-12S05A Vo: 5.0V (Eff Vs Io)
100%
95%
Efficiency (%
90%
85%
6.5V 12V 14V
80%
75% 0 1 2 3 4 5 6 7 8 9 10
Current Load (A)
Fig 33. SIP Efficiency Curves for Vout=5.0V (25C)
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
Typical Start Up
Ch1. Vin Ch2. Vout, Full load. Ch3. Q1-Vgs Ch4. Q2-Vgs
Typical Start Up with pre-bias
Ch1 : Enable Ch2 : Vout Ch3 : Output current at Full Load.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
Typical Output Noise and Ripple
Vin = 12Vdc , Vo=5.0V/10A Output with 1uF ceramic and 10uF tantalum capacitor
Typical Output Transient Response
Vin = 12Vdc , Vo=5.0V , 50% - 100% - 50% Load change , @0.1A/uS
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Output Voltage Set point adjustment.
Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
NFA Series converters can be programmed by applying a voltage between the TRIM and GND pins (Figure below). The following equation can be used to determine the value of Vtrim needed to obtain a desired output voltage Vo:
For example, to program the output voltage of NFA Series module to 3.3 Vdc, Vtrim is calculated as follows:
Circuit Configuration for programming Output voltage using external voltage source Table 1 provides Rtrim values for some common output voltages, whileTable 2 provides values of the external voltage source, Vtrim for the same common output voltages. Table 1 Table 2
By using a 1% tolerance trim resistor, set point tolerance of 2% is achieved as specified in the electrical specification.
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
Remote Sense:
All Celestica SMT/SIP power modules offer an option for remote sense. The remote sense compensates for any distribution drops to accurately control voltage at the point of load. The voltage between the sense pin to Vout pin should not exceed 0.5V.
Voltage Sequencing:
NFA series power modules offer the ability to precisely sequence output voltage rise. The sequence feature limits the output voltage to that presented at the Sequence pin. For example, if the sequence pin is connected to a variable voltage source, and the converter is enabled, output voltage will track the voltage applied to the sequence pin, to a maximum of the programmed output voltage. If this feature is not required, the sequence pin should remain unconnected. In practice, the Sequence pin of a lower voltage converter may be connected to a higher voltage source to ensure the lower voltage does not exceed the higher voltage during power on and power off. If multiple NFA series converters are used, all Sequence pins may be connected to the same higher voltage. In this way, all voltage rails will rise at the same rate, and cease to rise at their respective programmed output voltages.
SMT Lead free Reflow profile
1. Ramp up rate during preheat : 1.33 /Sec ( From 30 to 150 ) 2. Soaking temperature : 0.29 /Sec ( From 150 to 180 ) 3. Ramp up rate during reflow : 0.8 /Sec ( From 220 to 250 ) 4. Peak temperature : 250, above 220 40 to 70 Seconds
5. Ramp up rate during cooling : -1.56 /Sec ( From 220 to 150 )
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Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
Mechanical and pinning Information.
Given below is the outline drawing showing physical dimensions of the SIP & SMT package. The external dimensions for SMT package are 33.00mm X 13.46mm X 9.3mm.
BOTTOM VIEW OF BOARD
3.05 (0.120) 4.83 4.83 33.0 (1.30) 4.83 4.83 7.54 (0.297) 4.83 1.65 (0.065) 8.80 (0.346) max.
Recommended Pad Layout
Dimensions are in millimetes and(inches) 7.54(0.297) 4.83 4.83 4.83 4.83 3.05 (0.120) 4.83
(0.190) (0.190) (0.190) (0.190) (0.190)
(0.190) (0.190) (0.190) (0.190) (0.190)
SEQ
COM
+VO
TRIM +SENSE PGood 10.29 13.46 (0.405) (0.530) 10.29 (0.405)
PGood +SENSE TRIM
+VO
COM
SEQ 10.92 (0.430) +VIN
Top View of Board
ON/OFF
1.60 (0.063)
+VIN
ON/OFF
SURFACE MOUNT CONTACT
1.91 (0.075) 1.22 (0.048) L1 INDUCTOR
0.64 (0.025)
2.84 (0.112) Dimensions are in millimeters(Inches)
29.90 (1.177) PAD SIZE MIN:3.556x2.413(0.140x0.095) MAX:4.19x2.79(0.165x0.110)
Tolerances : X.X = 0.5mm(0.02in), X.XX = 0.25mm(0.010in),unless otherwise noted.
Whereas, the external dimensions of the SIP version are 50.8mm X 12.95mm X 8.30mm.
SIZE SIP
2.00(50.8)
0.327(8.30)max. 0.23(5.8)
12345 0.14(3.6) 0.100(2.54) 0.400(10.20)
6 7 8 9 10 11 12 0.510(12.95) 0.010(0.25) min. 0.025(0.64) 0.900(22.90) 0.050(1.30) 0.28(7.1) 0.025(0.64)
0.29(7.4)
LAYOUT PATTERN TOP VIEW
0.33(8.4)
All Dimmension In Inches(mm) Tolerance : .XX= 0.02 ( .X= 0.5 ) .XXX= 0.010 ( .XX= 0.25 )
1.1mm PLATED THROUGH HOLE 1.6mm PAD SIZE
PIN CONNECTION Pin FUNCTION +Output 1 +Output 2 3 +Sense +Output 4 5 Common PGood 6 Common 7 +V Input 8 +V Input 9 Sequence 10 Sequency 11 Trim 12 On/Off Control
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Safety Considerations (Approvals Pending)
Non-Isolated 10A SIP/SMT DC/DC
VOLANT NFA010 SERIES
The NFA series of converters are certified to IEC/EN/CSA/UL 60950. If this product is built into information technology equipment, the installation must comply with the above standard. An external input fuse (no more 20 A recommended) must be used to meet the above requirements. The output of the converter [Vo(+)/Vo(-)] is considered to remain within SELV limits when the input to the converter meets SELV or TNV-2 requirements. The converters and materials meet UL 94V-0 flammability ratings.
Ordering Information
Part Number NFA0101500B0C NFA0101500S0C NFA0101501B0C NFA0101501S0C Vin* 6.0V - 14.0V 6.0V - 14.0V 6.0V - 14.0V 6.0V - 14.0V Vout 0.75V - 5.0V 0.75V - 5.0V 0.75V - 5.0V 0.75V - 5.0V Iout 10A 10A 10A 10A Enable Logic Negative Negative Positive Positive Pin Length 0.139" SMT 0.139" SMT
* An input voltage of 6.5 Volts is required for 5 Volt output at full load.
Label Information
NFA0101500B0-XC
C = RoHS Compliant X = Factory control character (not required when ordering) 0 = Standard. (No PGood option) P = Power Good Option Pin Length Option B=0.139" S=SMT Enable Logic, 0 for-ve, 1 for +ve Iout Place Holder Vout Range F=Fixed A=Adjustable Vin (value or range) C= 3.3V -5.0V E= 8.3V-14V F= 6.0V-14V Vout
Non-Isolated Family RoHS Compliant
The NFA series of converters is in compliance with the European Union Directive 2002/95/EC (RoHS) with repsect to the following sustances: lead (Pb), mercury (Hg), cadmium (Cd), hexavalent chromium, polybrominated biphenyls (PBB) or polybrominated diphenyl ethers (PBDE).
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