IRF AFL27003R3SXES Hybrid-high reliability dc/dc converter Datasheet

PD - 94528C
AFL5003R3S
50V Input, 3.3V Output
HYBRID-HIGH RELIABILITY
DC/DC CONVERTER
Description
The AFL Series of DC/DC converters feature high power
density with no derating over the full military temperature
range. This device is offered as part of a complete family
of converters providing single and dual output voltages
originally created to operate over a broad input voltage
range of 28V to 270V with output power ranging from
66W to 120W. For applications requiring higher output
power, multiple converters can be operated in parallel.
The internal current sharing circuits assure equal current
distribution among the paralleled converters. This series
incorporates International Rectifier’s proprietary
magnetic pulse feedback technology providing optimum
dynamic line and load regulation response. This
feedback system samples the output voltage at the pulse
width modulator fixed clock frequency, nominally 550
KHz. Multiple converters can be synchronized to a system
clock in the 500KHz to 700KHz range or to the
synchronization output of one converter. Under voltage
lockout, primary and secondary referenced inhibit, soft
start and load fault protection are provided on all models.
These converters are hermetically packaged in two
enclosure variations, utilizing copper core pins to
minimize resistive DC losses. Three lead styles are
available, each fabricated using International Rectifier’s
rugged ceramic lead-to-package seal assuring long term
hermeticity in the most harsh environments.
AFL
Features
n
n
n
n
n
n
n
n
n
n
n
n
n
n
n
30V To 80V Input Range
3.3V Output
High Power Density - 50W/in3
66W Output Power
Parallel Operation with Stress and Current
Sharing
Low Profile (0.380") Seam Welded Package
Ceramic Feed thru Copper Core Pins
High Efficiency - to 74%
Full Military Temperature Range
Continuous Short Circuit and Overload
Protection
Remote Sensing Terminals
Primary and Secondary Referenced
Inhibit Functions
Line Rejection > 40dB - DC to 50KHz
External Synchronization Port
Fault Tolerant Design
Manufactured in a facility fully qualified to MIL-PRF38534, these converters are fabricated utilizing DSCC
qualified processes. For available screening options,
refer to device screening table in the data sheet.
Variations in electrical, mechanical and screening can
be accommodated. Contact IR Santa Clara for special
requirements.
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1
12/12/06
AFL5003R3S
Specifications
Absolute Maximum Ratings
Input voltage
Soldering temperature
Operating case temperature
Storage case temperature
-0.5V to +50VDC
300°C for 10 seconds
-55°C to +125°C
-65°C to +135°C
Electrical Performance Characteristics -55°C < TCASE < +125°C, 30V< VIN < 80V unless otherwise specified.
Parameter
Group A
Subgroups
Test Conditions
INPUT VOLTAGE
Note 6
OUTPUT VOLTAGE
V IN = 50 Volts, 100% Load
1
2, 3
Nom
Max
Unit
30
50
80
V
3.27
3.30
3.33
V
3.23
3.37
VIN = 30, 50, 80 Volts,, Note 6
OUTPUT CURRENT
20
Note 6
OUTPUT POWER
MAXIMUM CAPACITIVE LOAD
4
OUTPUT VOLTAGE
TEMPERATURE COEFFICIENT
OUTPUT VOLTAGE REGULATION
Line
Load
1, 2, 3
Inhibit 1
Inhibit 2
-0.015
+0.015
%/°C
-20
+20
mV
-35
+35
VIN = 30, 50, 80 Volts,, 100% Load,
BW = 10MHz
INPUT RIPPLE CURRENT
1, 2, 3
30
VIN = 50 Volts,
I OUT = 0
80
100
5.00
50
Pin 4 Shorted to Pin 2
Pin 12 Shorted to Pin 8
VIN = 50 Volts, 100% Load
B.W. = 10MHz
V OUT = 90% V NOM
CURRENT LIMIT POINT
Expressed as a Percentage
of Full Rated Load
VIN = 50 Volts, 100% Load
Note 1, 6
1, 2, 3
1
2, 3
1, 2, 3
1, 2, 3
W
µF
10,000
No Load, 50% Load, 100% Load
VIN = 30, 50, 80 Volts,
INPUT CURRENT
No Load
66
A
Note 1
1, 2, 3
OUTPUT RIPPLE VOLTAGE
mV pp
mA
60
mA pp
125
115
140
%
33
W
Note 5
1
2
3
115
105
125
VIN = 50 Volts,
LOAD FAULT POWER DISSIPATION
Overload or Short Circuit
1, 2, 3
EFFICIENCY
1, 2, 3
SWITCHING FREQUENCY
1, 2, 3
ISOLATION
Min
1
MTBF
VIN = 50 Volts, 100% Load
72
74
500
550
%
600
KHz
Input to Output or Any Pin to Case
(except Pin 3). Test @ 500VDC
100
MΩ
MIL-HDBK-217F, AIF @ TC = 40°C
300
KHrs
For Notes to Specifications, refer to page 3
2
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AFL5003R3S
Elecrical Performance Characteristics (Continued)
Parameter
ENABLE INPUTS (Inhibit Function)
Converter Off
Sink Current
Converter On
Sink Current
SYNCHRONIZATION INPUT
Frequency Range
Pulse Amplitude, Hi
Pulse Amplitude, Lo
Pulse Rise Time
Pulse Duty Cycle
Group A
Subgroups
1, 2, 3
1, 2, 3
Test Conditions
Min
Logical Low, Pin 4 or Pin 12
Note 1
Logical High, Pin 4 and Pin 12 - Note 9
Note 1
-0.5
1, 2, 3
1, 2, 3
1, 2, 3
Nom
2.0
500
2.0
-0.5
Note 1
Note 1
20
Max
Unit
0.8
100
50
100
V
µA
V
µA
700
10
0.8
100
80
KHz
V
V
ns
%
Note 2, 8
LOAD TRANSIENT RESPONSE
Amplitude
Recovery
4, 5, 6
4, 5, 6
Load Step 50% ⇔ 100%
-450
450
200
mV
µs
Amplitude
Recovery
4, 5, 6
4, 5, 6
Load Step 10% ⇔ 50%
-450
450
400
mV
µs
-500
500
500
mV
µs
250
120
mV
ms
Note 1, 2, 3
LINE TRANSIENT RESPONSE
VIN Step = 30 ⇔ 80 Volts
Amplitude
Recovery
TURN-ON CHARACTERISTICS
Overshoot
Delay
VIN = 30, 50, 80 Volts,. Note 4
4, 5, 6
4, 5, 6
Enable 1, 2 on. (Pins 4, 12 high or open)
LOAD FAULT RECOVERY
Same as Turn On Characteristics.
LINE REJECTION
MIL-STD-461, CS101, 30Hz to 50KHz
Note 1
40
50
dB
Notes to Specifications:
1.
2.
3.
4.
5.
6.
7.
8.
Parameters not 100% tested but are guaranteed to the limits specified in the table.
Recovery time is measured from the initiation of the transient to where VOUT has returned to within ±1.0% of
VOUT at 50% load.
Line transient transition time ≥ 100µs.
Turn-on delay is measured with an input voltage rise time of between 100V and 500V per millisecond.
Current limit point is that condition of excess load causing output voltage to drop to 90% of nominal.
Parameter verified as part of another test.
All electrical tests are performed with the remote sense leads connected to the output leads at the load.
Load transient transition time ≥ 10µs.
9.
Enable inputs internally pulled high. Nominal open circuit voltage
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≈ 4.0VDC.
3
AFL5003R3S
Block Diagram
Figure I. AFL Single Output
+ Input 1
Input
Filter
Enable 1 4
Output
Filter
Primary
Bias Supply
7
+Output
10
+Sense
Current
Sense
Sync Output
5
Sync Input 6
Case
Control
FB
3
Error
Amp
& Ref
Share
Amplifier
11 Share
12 Enable 2
Sense
Amplifier
Input Return 2
Circuit Operation and Application Information
The AFL series of converters employ a forward switched
mode converter topology. (refer to Figure I.) Operation of
the device is initiated when a DC voltage whose magnitude
is within the specified input limits is applied between pins 1
and 2. If pin 4 is enabled (at a logical 1 or open) the primary
bias supply will begin generating a regulated housekeeping
voltage bringing the circuitry on the primary side of the
converter to life. Two power MOSFETs used to chop the
DC input voltage into a high frequency square wave, apply
this chopped voltage to the power transformer. As this
switching is initiated, a voltage is impressed on a second
winding of the power transformer which is then rectified and
applied to the primary bias supply. When this occurs, the
input voltage is shut out and the primary bias voltage
becomes exclusively internally generated.
The switched voltage impressed on the secondary output
transformer winding is rectified and filtered to provide the
converter output voltage. An error amplifier on the secondary
side compares the output voltage to a precision reference
and generates an error signal proportional to the difference.
This error signal is magnetically coupled through the
feedback transformer into the controller section of the
converter varying the pulse width of the square wave signal
driving the MOSFETs, narrowing the width if the output
voltage is too high and widening it if it is too low.
4
Return Sense
Output Return
not used, the sense leads should be connected to their
respective output terminals at the converter. Figure III.
illustrates a typical application.
Inhibiting Converter Output (Enable)
As an alternative to application and removal of the DC
voltage to the input, the user can control the converter
output by providing TTL compatible, positive logic signals
to either of two enable pins (pin 4 or 12). The distinction
between these two signal ports is that enable 1 (pin 4) is
referenced to the input return (pin 2) while enable 2 (pin 12)
is referenced to the output return (pin 8). Thus, the user
has access to an inhibit function on either side of the isolation
barrier. Each port is internally pulled “high” so that when
not used, an open connection on both enable pins permits
normal converter operation. When their use is desired, a
logical “low” on either port will shut the converter down.
Figure II. Enable Input Equivalent Circuit
+5.6 V
Pin 4 or
Pin 12
1N4148
100K
290K
Disable
2N3904
Remote Sensing
Connection of the + and - sense leads at a remotely located
load permits compensation for resistive voltage drop
between the converter output and the load when they are
physically separated by a significant distance. This
connection allows regulation to the placard voltage at the
point of application. When the remote sensing features is
9
8
180K
Pin 2 or
Pin 8
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AFL5003R3S
high level of +2.0V. The sync output of another converter
which has been designated as the master oscillator provides
a convenient frequency source for this mode of operation.
When external synchronization is not required, the sync in
pin should be left unconnected there by permitting the
converter to operate at its’ own internally set frequency.
Internally, these ports differ slightly in their function. In use,
a low on Enable 1 completely shuts down all circuits in the
converter while a low on Enable 2 shuts down the secondary
side while altering the controller duty cycle to near zero.
Enabling by the use of either port is transparent to the user
save for minor differences in idle current. (See specification
table).
The sync output signal is a continuous pulse train set at
550 ± 50KHz, with a duty cycle of 15 ± 5.0%. This signal is
referenced to the input return and has been tailored to be
compatible with the AFL sync input port. Transition times
are less than 100ns and the low level output impedance is
less than 50Ω. This signal is active when the DC input
voltage is within the specified operating range and the
converter is not inhibited. This output has adequate drive
reserve to synchronize at least five additional converters.
A typical synchronization connection option is illustrated in
Figure III.
Synchronization of Multiple Converters
When operating multiple converters, system requirements
often dictate operation of the converters at a common
frequency. To accommodate this requirement, the AFL
series converters provide both a synchronization input and
output.
The sync input port permits synchronization of an AFL
converter to any compatible external frequency source
operating between 500KHz and 700KHz. This input signal
should be referenced to the input return and have a 10% to
90% duty cycle. Compatibility requires transition times less
than 100ns, maximum low level of +0.8V and a minimum
Figure III. Preferred Connection for Parallel Operation
Power
Input
12
1
Vin
Enable 2
Rtn
Share
Case
Enable 1
Optional
Synchronization
Connection
AFL
+ Sense
- Sense
Sync Out
Return
Sync In
+ Vout
7
6
Share Bus
12
1
Enable 2
Vin
Share
Rtn
Case
Enable 1
AFL
+ Sense
- Sense
Sync Out
Return
Sync In
+ Vout
6
1
to Load
7
12
Vin
Enable 2
Rtn
Share
Case
Enable 1
AFL
+ Sense
- Sense
Sync Out
Return
Sync In
+ Vout
6
7
(Other Converters)
Parallel Operation-Current and Stress Sharing
Figure III. illustrates the preferred connection scheme for
operation of a set of AFL converters with outputs operating
in parallel. Use of this connection permits equal sharing of a
load current exceeding the capacity of an individual AFL
among the members of the set. An important feature of the
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AFL series operating in the parallel mode is that in addition
to sharing the current, the stress induced by temperature
will also be shared. Thus if one member of a paralleled set
is operating at a higher case temperature, the current it
provides to the load will be reduced as compensation for
the temperature induced stress on that device.
5
AFL5003R3S
When operating in the shared mode, it is important that
symmetry of connection be maintained as an assurance of
optimum load sharing performance. Thus, converter outputs
should be connected to the load with equal lengths of wire of
the same gauge and sense leads from each converter should
be connected to a common physical point, preferably at the
load along with the converter output and return leads. All
converters in a paralleled set must have their share pins
connected together. This arrangement is diagrammatically
illustrated in Figure III. showing the outputs and sense pins
connected at a star point which is located close as possible
to the load.
As a consequence of the topology utilized in the current
sharing circuit, the share pin may be used for other functions.
In applications requiring a single converter, the voltage
appearing on the share pin may be used as a “current
monitor”. The share pin open circuit voltage is nominally
+1.00V at no load and increases linearly with increasing
output current to +2.20V at full load. The share pin voltage
is referenced to the output return pin.
Thermal Considerations
Because of the incorporation of many innovative
technological concepts, the AFL series of converters is
capable of providing very high output power from a package
of very small volume. These magnitudes of power density
can only be obtained by combining high circuit efficiency
with effective methods of heat removal from the die junctions.
This requirement has been effectively addressed inside the
device; but when operating at maximum loads, a significant
amount of heat will be generated and this heat must be
conducted away from the case. To maintain the case
temperature at or below the specified maximum of 125°C,
this heat must be transferred by conduction to an
appropriate heat dissipator held in intimate contact with the
converter base-plate.
Because effectiveness of this heat transfer is dependent
on the intimacy of the baseplate/heatsink interface, it is
strongly recommended that a high thermal conductivity
heat transferance medium is inserted between the baseplate
and heatsink. The material most frequently utilized at the
factory during all testing and burn-in processes is sold
under the trade name of Sil-Pad® 4001. This particular
product is an insulator but electrically conductive versions
are also available. Use of these materials assures
maximum surface contact with the heat dissipator thereby
compensating
for minor variations of either surface. While other available
types of heat conductive materials and compounds may
provide similar performance, these alternatives are often
less convenient and are frequently messy to use.
A conservative aid to estimating the total heat sink surface
area (A HEAT SINK ) required to set the maximum case
temperature rise (∆T) above ambient temperature is given
by the following expression:
.
⎧ ∆T ⎫ −143
⎬
A HEAT SINK ≈ ⎨
− 3.0
⎩ 80P 0.85 ⎭
where
∆T = Case temperature rise above ambient
⎧ 1
⎫
− 1⎬
P = Device dissipation in Watts = POUT ⎨
⎩ Eff
⎭
As an example, it is desired to maintain the case temperature
of an AFL27015S at ≤ +85°C in an area where the ambient
temperature is held at a constant +25°C; then
∆T = 85 - 25 = 60°C
From the Specification Table, the worst case full load
efficiency for this device is 83%; therefore the power
dissipation at full load is given by
⎧ 1
⎫
P = 120 • ⎨
− 1⎬ = 120 • ( 0.205) = 24.6W
⎩ .83 ⎭
and the required heat sink area is
⎫ −1.43
⎧
60
⎬
− 3.0 = 71 in2
A HEAT SINK = ⎨
⎩ 80 • 24.6 0.85 ⎭
Thus, a total heat sink surface area (including fins, if any) of
71 in2 in this example, would limit case rise to 60°C above
ambient. A flat aluminum plate, 0.25" thick and of approximate
dimension 4" by 9" (36 in2 per side) would suffice for this
application in a still air environment. Note that to meet the
criteria in this example, both sides of the plate require
unrestricted exposure to the ambient air.
1Sil-Pad is a registered Trade Mark of Bergquist, Minneapolis, MN
6
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AFL5003R3S
Input Filter
The AFL5003R3S series converters incorporate a single
stage LC input filter whose elements dominate the input
load impedance characteristic during the turn-on sequence.
The input circuit is as shown in Figure IV.
Figure IV. Input Filter Circuit
Finding a resistor value for a particular output voltage, is
simply a matter of substituting the desired output voltage
and the nominal device voltage into the equation and solving
for the corresponding resistor value.
Figure V. Connection for VOUT Adjustment
Enable 2
0.75µH
Share
Pin 1
AFL5003R3S
2.7µfd
+ Sense
RADJ
- Sense
Return
To Load
+ Vout
Pin 2
Caution: Do not set Radj < 500Ω
Undervoltage Lockout
A minimum voltage is required at the input of the converter
to initiate operation. This voltage is set to 26.5V ±1.5V. To
preclude the possibility of noise or other variations at the
input falsely initiating and halting converter operation, a
hysteresis of approximately 2.0V is incorporated in this
circuit. Thus if the input voltage drops to 24.5V ± 1.5V, the
converter will shut down and remain inoperative until the
input voltage returns to ≈ 25V.
Output Voltage Adjust
In addition to permitting close voltage regulation of remotely
located loads, it is possible to utilize the converter sense
pins to incrementally increase the output voltage over a
limited range. The adjustments made possible by this method
are intended as a means to “trim” the output to a voltage
setting for some particular application, but are not intended
to create an adjustable output converter. These output
voltage setting variations are obtained by connecting an
appropriate resistor value between the +sense and -sense
pins while connecting the -sense pin to the output return pin
as shown in Figure V. below. The range of adjustment and
corresponding range of resistance values can be determined
by use of the following equation.
⎧
⎫
VNOM
⎬
Radj = 100 • ⎨
⎩VOUT - VNOM -.025 ⎭
Where
Attempts to adjust the output voltage to a value greater than
120% of nominal should be avoided because of the potential
of exceeding internal component stress ratings and
subsequent operation to failure. Under no circumstance
should the external setting resistor be made less than 500Ω.
By remaining within this specified range of values, completely
safe operation fully within normal component derating limits
is assured.
Examination of the equation relating output voltage and
resistor value reveals a special benefit of the circuit topology
utilized for remote sensing of output voltage in the AFL50XXS
series of converters. It is apparent that as the resistance
increases, the output voltage approaches the nominal set
value of the device. In fact the calculated limiting value of
output voltage as the adjusting resistor becomes very large
is ≈ 25mV above nominal device voltage.
The consequence is that if the +sense connection is
unintentionally broken, an AFL50XXS has a fail-safe output
voltage of Vout + 25mV, where the 25mV is independent of
the nominal output voltage. It can be further demonstrated
that in the event of both the + and - sense connections
being broken, the output will be limited to Vout + 440mV.
This 440mV is also essentially constant independent of the
nominal output voltage. While operation in this condition is
not damaging to the device, not all performance parameters
will be met.
VNOM = device nominal output voltage, and
VOUT = desired output voltage
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7
AFL5003R3S
Mechanical Outlines
Case X
Case W
Pin Variation of Case Y
3.000
ø 0.128
2.760
0.050
0.050
1
12
0.250
0.250
0.200 Typ
Non-cum
6
7
1.260 1.500
1.000
Ref
1.000
Pin
ø 0.040
Pin
ø 0.040
0.220
2.500
0.220
2.800
2.975 max
0.525
0.238 max
0.42
0.380
Max
0.380
Max
Case Y
Case Z
Pin Variation of Case Y
1.150
0.300
ø 0.140
0.25 typ
0.050
0.050
1
12
0.250
0.250
1.000
Ref
6
1.750
1.000
Ref
0.200 Typ
Non-cum
7
1.500 1.750 2.00
Pin
ø 0.040
0.375
Pin
ø 0.040
0.220
0.220
0.36
2.500
2.800
2.975 max
0.525
0.238 max
0.380
Max
0.380
Max
Tolerances, unless otherwise specified:
.XX
.XXX
=
=
±0.010
±0.005
BERYLLIA WARNING: These converters are hermetically sealed; however they contain BeO substrates and should not be ground or subjected to any other
operations including exposure to acids, which may produce Beryllium dust or fumes containing Beryllium
8
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AFL5003R3S
Device Screening
Requirement
MIL-STD-883 Method
Temperature Range
No Suffix
ES
d
-20°C to +85°C -55°C to +125°C
Element Evaluation
HB
e -55°C to +125°C
CH
-55°C to +125°C
MIL-PRF-38534
N/A
N/A
N/A
Class H
2023
N/A
N/A
N/A
N/A
Internal Visual
2017
c
Yes
Yes
Yes
Temperature Cycle
1010
N/A
Cond B
Cond C
Cond C
Constant Acceleration
2001, Y1 Axis
N/A
500 Gs
3000 Gs
3000 Gs
PIND
2020
N/A
N/A
N/A
N/A
48 hrs@hi temp
Non-Destructive
Bond Pull
Burn-In
1015
N/A
Final Electrical
MIL-PRF-38534
25°C
( Group A )
& Specification
25°C
d
160 hrs@125°C 160 hrs@125°C
-55°C, +25°C,
-55°C, +25°C,
+125°C
+125°C
PDA
MIL-PRF-38534
N/A
N/A
N/A
10%
Seal, Fine and Gross
1014
Cond A
Cond A, C
Cond A, C
Cond A, C
Radiographic
2012
N/A
N/A
N/A
N/A
External Visual
2009
Yes
Yes
Yes
c
Notes:
 Best commercial practice
‚ Sample tests at low and high temperatures
ƒ -55°C to +105°C for AHE, ATO, ATW
Part Numbering
Pin Designation
Pin #
Designation
1
+ Input
2
Input Return
3
Case Ground
4
Enable 1
5
Sync Output
6
Sync Input
7
+ Output
8
Output Return
9
Return Sense
10
+ Sense
11
Share
12
Enable 2
Model
AFL 50 03R3 S X /CH
Screening Level
(Please refer to Screening Table)
Input Voltage
No suffix, ES, HB, CH
28 = 28V
50 = 50V
120 = 120V
270 = 270V
Case Style
Output Voltage
W, X, Y, Z
Output
S = Single
03R3 = 3.3V
WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245, Tel: (310) 322 3331
IR SANTA CLARA: 2270 Martin Av., Santa Clara, California 95050, Tel: (408) 727-0500
Visit us at www.irf.com for sales contact information.
Data and specifications subject to change without notice. 12/2006
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