Vicor F3D480T20A Vi chip pfm power factor module Datasheet

PRELIMINARY
PFM
V•I Chip PFM
Power Factor Module
•
•
•
•
•
•
•
•
•
F3D480T20A
DC+
Input: rectified 120/240 Vac sinusoidal
Output: 48 Vdc programmable
Output power: Up to 200 W
4,242 Vdc reinforced insulation
90% efficiency
375 W/in3 power density
Low profile: 0.25”
Surface mount J Lead package
Meets EN 61000-3-2 harmonic current limits
Product Description
™
+IN
PR
SC
SG
F3D480T20A
BV
RSV
PC
8395846576834856
PFM™
–IN
+Out
Pb
S
C
NRTL
US
–Out
U.S. & FOREIGN PATS. AND PATS. PENDING. MADE IN U.S.A.
©
Actual Size
Absolute Maximum Ratings
The PFM (Power Factor Module) is a V•I Chip
power component that converts a rectified
120/240 Vac line to an isolated, regulated DC
voltage programmable from 26 V to 48 V.
Rated at 200 W, the PFM meets EN61000-3-2
harmonic current limits and is available in a double
VIC package measuring only 1.69" (43,0) x
1.26" (32,0) x 0.25" (6,2). The PFM power density
is 375 W/in3.
The PFM is the front-end V•I Chip for AC-DC
power systems. It requires only a rectifier, input
filter and an output capacitor to provide
a high density, power factor corrected, 200 W
power supply. The high operating frequency and
soft switching allow miniaturization of power train
components and make EMI filter components
smaller than those required by lower frequency,
hard switching converters. Output energy storage
is accomplished at SELV levels providing packaging
and interconnect flexibility not available with
conventional AC Front Ends.
PFMs may be paralleled with power sharing for
added power or redundancy in single or three
phase systems. The output voltage can be
programmed to meet the requirements of system
loads and/or additional downstream conversion
devices such as Vicor’s Pre Regulator Modules (PRMs)
and Voltage Transformation Modules (VTMs).
Parameter
Input voltage (+IN to -IN)
Operating
Non-operating
Input voltage slew rate
PC to -IN
BV to -IN
PR to -OUT
SC
Output voltage (+OUT to -OUT)
Output current
Dielectric withstand (input to output)
Temperature
Operating junction
Storage
Case peak temperature during reflow
Case peak temperature during reflow
Min
Max
Unit
Notes
90
0
264
450
25
7
50
7
1.5
55
6
4,242
Vrms
Vdc
V/µs
Vdc
Vdc
Vdc
Vdc
Vdc
A
Vdc
Rectified AC sinusoidal
100 ms
125
150
225
245
˚C
˚C
˚C
˚C
-0.3
-0.3
-0.3
-0.3
-0.5
-55
-65
Reinforced insulation
1 Min
M-Grade
M-Grade
MSL 3
MSL 6
Part Numbering
F
3
Power Factor
Module
D
Input Designator
3 = 115/230 Vac
Package
D = Double VIC w/ J leads
Input Filter / Rectifier
480
T
Output Voltage
Designator
(VOUT x10)
20
A
Output Power
Designator
(POUT x 0.1)
A = Analog
Control
Product Grade Temperatures (°C)
Grade
Storage
Operating
T
-40 to150 -40 to125
M
-65 to150 -55 to125
PFM
L
48 Vdc
200 W
Load
N
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 1 of 14
PRELIMINARY
Electrical characteristics
Rectified AC Input Source
(Conditions: 25˚C case, 75% rated load and specified input voltage range unless otherwise specified.)
The PFM operates from a full bridge rectified AC line with the following characteristics:
Parameter
Min
Typ
Max
Unit
Note
The PFM is not designed to support output load
when the input is 132 to 175 Vrms
Source voltage low range
90
132
Vrms
Source voltage high range
180
264
Vrms
Source frequency range
47
63
Hz
Input
(Operating from AC input source)
Parameter
Min
Typ
Max
Unit
Note
82
85
Vrms
Source voltage
Overvoltage shut down
265
275
Power factor
0.94
Undervoltage shut down
Vrms
Source voltage
47 – 63 Hz
Inrush current
5
A pk
Output
Parameter
Min
Typ
Max
Unit
Note
Set point
Output may be trimmed down from factory set point
via external trim resistor. See page 4, SC pin
47.5
48.0
48.5
Vdc
Output voltage trim range
26
48
48.0
Vdc
Output current
0
4.1
A
Vout = 48 Vdc
Output power
0
200
W
Vout = 48 Vdc see Fig. 22 for heat sink information
OVP set point
56
58
Vdc
Line regulation
0.3
1
%
Load regulation
0.5
1
%
Efficiency
88
90
No load power dissipation
0.75
Current share accuracy
Switching frequency ripple
Line frequency ripple
%
120 Vrms 75% load
W
Meets Energy Star no load limit
5
10
%
240
300
mV pk-pk
350
750
mV rms
1.12
2.0
V pk-pk
2.5
5.0
S
~1.2 MHz with 10 µF ceramic bypass capacitance
With 10,000 µF output capacitor
Start up time
From application of power
2.0
Dynamic response
Voltage deviation
Recovery time
6
500
No overshoot
%
mS
Of Vout
Output capacitance
1,500
2,200
10,000
µF
Hold-up capacitance
1,500
2,200
10,000
µF
Required for PFC. Output ripple is a function of output
and hold-up capacitance. See Fig.8 for hold-up time.
5.5
6.0
A
Current limited
Short circuit protection
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 2 of 14
PRELIMINARY
Electrical (cont.)
(conditions: 25˚C case, 75% rated load and specified input voltage range)
Control Pins (See page 4 for pin description)
Pin
Min
BV (Bias Voltage)
-0.5
Typ
Max
Unit
48
V
Note
Referenced to -IN
5.2
Vdc
Referenced to -IN
PC (Primary Control)
DC voltage
4.8
5.0
Module disable threshold
2.3
2.4
Module enable threshold
2.5
Disable hysteresis
100
Current limit
2.0
Vdc
2.6
Vdc
3.5
mA
mV
2.7
PC pulled low
Analog control
PR (Parallel Port)
Voltage
0.6
Source current
7.5
1
V
Referenced to SG, see PR pin pg.4
mA
External capacitance
100
pF
1.25
Vdc
SC (Secondary Control)
Voltage
1.23
1.24
Internal capacitance
1.0
Referenced to SG
nF
External capacitance
0.7
µF
General
Parameter
Min
Typ
Max
Unit
Note
Over temperature shut down
Junction-to-case thermal impedance
125
130
0.6
135
°C
°C/W
Junction temperature
Case-to-ambient thermal impedance
Dielectric withstand
Insulation resistance
Capacitance
Leakage current
Line fuse Rating
2.3
°C/W
4,242
10
110
30
250
4
Mechanical
Weight
Length
Width
Height
1.0 / 30
1.69 / 43
1.26 / 32
0.25 / 6.2
Vdc
M ohms
pF
µA
Vac
A
Always ascertain and observe applicable safety,
regulatory and agency specifications
oz / g
in / mm
in / mm
in / mm
Contact Vicor for information regarding soldering of
the PFM to printed circuit boards.
Reflow parameters
Resistance to cleaning
Solvents
Agency approvals (pending)
46 mm x 46 mm x11mm heatsink #31474
with 300 LFM
Input to output
Input to output
Input to output
IEC 68-2-45 XA
Method 1
Water
Isopropyl alcohol
cTÜVus
CE
+55 ±5˚C
+35 ±5˚C
UL/CSA 60950, EN 60950
Low voltage directive
Electromagnetic Compatibility (configured as illustrated in Fig. 18 )
Harmonic currents
EN 61000-3-2, Amendment 14
See Fig. 11
Line disturbance / immunity
EN 61000-4-11
Interruptions and brownouts
Transient / surge immunity
EN 61000-4-5
2 kV – 50 µs line or neutral to earth
1 kV – 50 µs line to neutral
Conducted emissions
EN 55022, Level B
Flicker / inrush
With filter ( see Fig. 18 )
EN 61000-3-3
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 3 of 14
PRELIMINARY
Pin/Control Functions
SC – secondary control (analog control models only)
Power Factor Module (PFM)
DC+
PR
SC
SG
The output voltage may be programmed, margined or trimmed down
by connecting a voltage source or resistor between the SC port and SG
port. The slew rate of the output voltage may be reduced by controlling
the rate-of-rise for the voltage at the SC port ( e.g. to limit inrush into a
capacitive load).
+IN
BV
RSV
PC
+OUT
The following expression should be used to calculate the required set
point resistor value. No resistor is required if the user desires a nominal
48 V output.
-IN
-OUT
BOTTOM VIEW
R = ( Vo / (48 - Vo) ) 30.1 kΩ
Figure 1— PFM pin out
Where: R = the set point resistor
Vo = the desired output voltage set point
Primary side
Example:
+IN / -IN – DC voltage
The PFM operates from a full wave rectified AC voltage within the
limits shown on page 2. PFMs have internal over / undervoltage
lockout functions that prevent operation outside of the specified rms
input range. PFMs will turn on when the input voltage rises above its
undervoltage lockout. If the input voltage exceeds the overvoltage
lockout, PFMs will shut down until the overvoltage fault clears.
Vo
R
42 V 211 kΩ
36 V 90.3 kΩ
Table 1
1.25 V
Full Scale
BV - bias voltage
A 47 µF 50 V electrolytic capacitor must be connected between this
port and –IN to provide energy storage for the primary bias circuit.
μP
30.1 kΩ
RSV – reserved
ref
1.25 V
PC – primary control
The PFM voltage output is enabled when the PC pin is open circuit
(floating). To disable the PFM output voltage, the PC pin is pulled to
–IN. Open collector optocouplers, transistors, or relays can be used to
control the PC pin. When using multiple PFMs in a high power array,
the PC ports should be tied together to synchronize their turn on.
SC
1 nF
SG
Figure 2—Functional block diagram
Secondary side
DC+
SG – signal return (analog control models only)
A hold-up capacitor should be connected between this port and SG
to provide output hold-up in the event of an input power failure.
For 10 ms hold-up at full load, a 2,200 µF 50 V electrolytic capacitor
is recommended. DC+ should not be back driven.
This port should be used as reference for the SC, PR, and DC+ ports.
Care must be taken to insure there are no low impedance paths
between -OUT and SG. Such a path could allow current to bypass the
internal current sense resistor.
PR – parallel port (analog control models only)
+ OUT / -OUT – voltage output
The PR port signal, which is proportional to the PFM output power,
supports current sharing among PFMs. To enable current sharing, PR
ports should be interconnected. No bypass capacitance should be used
when interconnecting PR ports and steps should be taken to minimize
stray capacitance and noise coupling into this line (e.g, by minimizing
the width of PR port interconnect traces that lay over, or in proximity
to, signal grounds or power / ground planes). The PR port is referenced
to SG.
These ports provide the isolated DC output voltage. The –OUT pin is
separated from the SG (Signal Return) pin by the internal current
sensing resistor.
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Safety consideration
Care must be exercised to insure appropriate spacing, clearance and
creepage distances are maintained between line side terminals and
secondary SELV terminals.
Power Factor Module
F3D480T20A
Rev. 1.0
Page 4 of 14
PRELIMINARY
PFM Theory of Operation
The PFM power-processing module consists of two major functional
blocks: an Adaptive Voltage Transformation Module (VTM) that
interfaces directly to the rectified line followed by a microprocessor
controlled Post Regulator Module (PRM). In contrast to offline power
factor correction topologies, input current shaping and energy storage
are accomplished on the secondary side of the isolation boundary.
+IN
Adaptive VTM
The Adaptive VTM acts as a nearly ideal DC-to-DC transformer. It
accepts the rectified AC input from the power source, configures its
step down ratio, or K factor, based on the magnitude of the input
voltage, and produces an isolated DC output that instantaneously
tracks the input. The Adaptive VTM configures itself by paralleling
input cells in low voltage input mode or by series configuration of
input cells in high voltage input mode. Operating over the worldwide
AC mains, the Adaptive VTM reduces the voltage variation applied to
the PRM stage from 3 to1 to 1.5 to1. This reduction in voltage range
allows greater performance and economy than would be possible
without Adaptive Transformation, which is enabled by Vicor’s
proprietary class of Cascaded Topologies.
The PFM uses a Sine Amplitude Converter (SAC) Cascaded Topology
providing zero-voltage/zero-current switching through a low Q
resonant circuit to eliminate switching losses. The SAC can be
operated efficiently at high frequencies, typically in the 3 MHz range.
The high operating frequency allows miniaturization of power train
components with a commensurate increase in converter power
density. High operating frequency and soft switching makes EMI
filtering components smaller than those required by lower frequency,
hard switching converters.
To PRM
Control
–IN
Figure 3— 120 Vac input configuration
+IN
To PRM
Control
–IN
Figure 4— 240 Vac input configuration
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 5 of 14
PRELIMINARY
PFM Theory of Operation cont.
PRM with PFC
The output of the VTM drives the PFC/PRM. The PFC/PRM (Figure 5 ) is
a microprocessor controlled, high-efficiency, zero-voltage switching
buck-boost regulator providing output voltage regulation and input
current shaping. The input voltage, isolated and adaptively
transformed by the VTM, and the PRM’s output voltage and output
current are sampled by the microprocessor. The processor uses a digital
algorithm to develop a control signal used to simultaneously regulate
the output voltage and shape the module input current, providing
harmonic current reduction. This control signal is fed to the switch
management ASIC. This provides proper switch timing, maintaining
zero-voltage switching under all operating conditions. Energy storage
is accomplished outside the PFM by means of an output capacitor that
may be sized to meet the user’s hold up requirements.
DC+
External Cap
+OUT
To
External Cap
and
Load
From VTM
–OUT
ZVS Control
μ Controller
Figure 5 — The PRM with PFC
+IN
T2
1
Q1
2
T1
T2
2
Q2
Q5
+OUT
1
1
PC
BV
T2
T2
2
2
Q3
–OUT
T1
1
Q6
Frequency
Lock/Control
T2
2
1
T2
Proprietary Analog
Buck-Boost Control
1
Q4
VREF
1.25 V
30.1 kΩ
μP
1.25 V
Full Scale
PR
SG
SC
2
1 nF
–IN
Figure 6 — Functional block diagram of the PFM
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 6 of 14
PRELIMINARY
(conditions: 25˚C case, 75% rated load and specified input voltage range)
220
30
200
25
Hold-up Time (mS)
Output Power
Electrical
180
160
140
120
100
26
37
20
15
10
5
0
48
50
100
Output Voltage
150
200
Output Power (W)
Figure 7 — Output power rating vs. trimmed output voltage
Figure 8 — Hold up time with 2,200 µF output and hold-up
capacitors with 48 Vdc output
91
25.0
90
Power Dissipation (W)
Efficiency (%)
89
88
87
86
85
84
83
82
50
75
100
125
150
175
20.0
15.0
10.0
5.0
0.0
200
50
Output Power (W)
75
100
125
150
175
200
Output Power (W)
Figure 9 — Efficiency vs. Output Power (120 Vrms, 48 Vdc)
Figure 10 — Power Dissipation vs. Output Power (120 Vrms, 48 Vdc)
PFM Harmonic Current
2.50
Measured Value
Limit
2.00
+
DC+
4.0 A
Amperes
+In
1.50
Rectified
120 / 240 Vac
0.5 μF
600 V
+
47 μF
50 V
1.00
BV
RSV
PC
PR
SC
-In
Optional Hold-up Cap.
2,200 μF
50 V
SG
PFM
Output Cap.
+OUT
–
+
-OUT
+
2,200 μF
50 V
Load
0.50
0.00
3
5
7
9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39
Harmonic
Figure 11 — Harmonic Current vs. EN61000-3-2 limits (115 Vrms
180 W Out)
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Figure 12 — PFM test circuit
Power Factor Module
F3D480T20A
Rev. 1.0
Page 7 of 14
PRELIMINARY
Electrical (cont.)
Figure 13 — Typical Input Current (230 Vrms 200 W Out)
Figure 14 — Transient Response Input:120 Vac, 60 Hz
Output step load: 10% to 90% to 10%
Figure 15 — Output Ripple (Line frequency)
Figure 16 — Output Ripple (Switching frequency)
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 8 of 14
PRELIMINARY
Electrical (cont.)
PFM Applications
L2
HOLD-UP CAP
DC+
F1
L
+In
PR
SC
VC
PC
TM
IL
NC
PR
+
C4
R1
120 / 240 Vac
Filter/
Rectifier
+
BV
RSV
PC
SG
PFM
C1
F2
+OUT
-In
N
+Out
Factorized
Bus (Vf)
RCD
L1
1
2
4
3
C6
-OUT
R2
–In
–Out
L3
Refer to Fig.18
-In
VTM
K
Ro
+Out
-Out
1.2 Vdc
100 A
-Out
V048F015T100
P048F048T24AL
C2
TM
VC
PC
L
O
A
D
+Out
+In
ROS
+
+
C5
PRM-AL
+In
VH
SC
SG
OS
NC
CD
C3
Connect to a copper shield plane under the PFM
Ref Des
Description
F1
F2
C1
C2, C3
C4, C5
C6
L1
L2
Ros
RCD
R1
R2
Fuse, 3.15 A, 5x20
Fuse 6 A
47 μF, 50 V
4.7 nF, 250 V, Y2
2,200 μF, 50 V
88 μF 63 V
Dual winding inductor, 0.1 nH / winding
Ferrite bead, 6 A 33 ohm @ 100 MHz
2.9 K Ω
32.4 Ω
1/16 Watt for adj. see SC pin p.11
1/16 Watt 10 Ω
Vicor P/N
30707-476
19726-972
29852-R10
29187-33R0
Figure 17 — Typical FPA (Factorized Power Architecture) from the wall plug to the point of load. See PRM data sheet (P048F048T24AL) for
other output voltage / current options.
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 9 of 14
PRELIMINARY
Electrical (cont.)
Input Filter and Rectifier
The circuit shown below provides AC line rectification, transient suppression, and conducted emissions filtering to comply with standards imposed
by the EMC (Electromagnetic Compatibility) directive. These include the transient immunity standard EN 61000-4-5, and the conducted emissions
standard EN 55022, level B.
C10
C12
D10
R1
DC+
2
3 0
D1
L1
2 5
1
D2
+In
PR
SC
Z1
1
6
F1
L
D5
C1
120 / 240 VAC
C2
C3
Q1
C6
D7
C4
N
R2
Z2
D3
BV
RSV
PC
D8
C9
Z3
3
4
SG
PFM
+OUT
D6
D4
C16
D9
1
C7
C5
C8
C14
C15
-In
C11
C17
2
J2
-OUT
C13
Connect to a copper shield plane under the PFM
REF DES
C1 - C4
C5
C6
C7, C8, C14, C15
C9
C10 - C13
D1 - D4
Q1
D5, D6, D10
D7
D8
D9
F1
J1 - J3
L1
R1
R2
Z1
Z2, Z3
DESC
CAP X7R 0.1uF 630V 1812
CAP X7R 0.01uF 500V 1206
CAP 1uF 100V 1206
CAP 0.022uF 630V 1206
CAP 47uF 50V ALEL SMD
CAP 4.7nF 250V Y2
DIODE 3A 1KV UF SMD
MOSFET
TVS 200V 600W SMB
ZENER DIODE 15V
DIODE 1N4148
ZENER DIODE 24V
FUSE 3.15A 250V SMD
TERM BLOCK 2 POS SMD
CHOKE COMMON MODE
RES 200 1% 1206
RES 1K 1% 1206
SIDACTOR 200V
MOV 220V
MFG
TDK
KEMET
SAMSUNG
TDK
PANASONIC
MURATA
CENTRAL SEMI
VISHAY
ON SEMI
DIODES INC.
ON SEMI
DIODES INC.
LITTELFUSE
WECO
GOWANDA
KOA SPEER
KOA SPEER
LITTELFUSE
LITTELFUSE
MFG P/N
C4532X7R2J104MT000N
C1206C103KCRACTU
CL31B105KCHNNNE
C3216X7R2J223KT0L0U
ECE-V1HA470XP
GA355DR7GC472KY02L
CMR3U-10M
SUM45N25-58
P6SMB200AT3
BZT52C15
MMSD4148T1G
BZT52C24
0465 3.15
140-A-524-SMD/02
51-935
ERJ-P08J201V
RK73H1JT1001F
P2000SB
V240CH8
Figure 18 — Typical application circuit
PFM Evaluation Board
C16
PFM
C17
Figure 19 — The PFM evaluation board shown (actual size) above illustrates the layout and compact size of a complete AC to 48 Vdc, 200
Watt front end power supply using the PFM.
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 10 of 14
PRELIMINARY
Electrical (cont.)
PFM Applications
The block diagram below shows an example of a Factorized Power system from the wall plug to the point-of-load. The PFM directly regulates a
primary high power output through a VTM to provide voltage division. A secondary output is independently regulated with a PRM. Auxiliary
outputs are derived through a V•I Chip Bus Converter Module (BCM) and non-isolated POL converters.
Input Filter / Rectifier
PFM
VTM
L
NS
NP
120 / 240 Vac
Output 1
N
PRM
VTM
NS
NP
Output 2
L
BCM
NP
niPOL
NS
L
Output 3
niPOL
L
Output 4
Figure 20 — Typical application using Factorized Power Architecture (FPA)
The block diagram below shows a 400 Watt PFC front end with two PFMs in a parallel configuration. Higher power can be achieved by adding
additional PFMs.
PFM
Input Filter / Rectifier
48 Vdc
400 Watts
Load
L
120 / 240 Vac
PFM
N
Figure 21 — Two PFMs operated in parallel for additional power.
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 11 of 14
PRELIMINARY
Thermal Management
PFM
7
Case-to-ambient thermal resistance with
Heatsink #31474
Thermal Resistance (C/W)
6
5
4
3
2
1
0
0
200
400
600
800
1000
1200
Air Velocity (LFM)
Figure 22 — Case to ambient thermal resistance vs. airflow using heatsink #31474 (46mm x 46mm x 11mm) with MCMStrate 2 mil interface
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 12 of 14
PRELIMINARY
Mechanical Drawings
43.0
1.69
6.2
0.25
36.99
1.456
3.01
0.118
(6)
3.01
0.118
1.10
0.043
26.00
1.024
22.00
0.866
24.00
0.945
(2)
8.10
0.319
OUTPUT
30.00
1.181
C
L
1.22
0.048
8.56
0.337
INPUT
28.00
1,102
OUTPUT
32.0
1.260
INPUT
(3)
22.54
0.887
14.94
0.588
11.10
16.94
0.437 12.94
0.667
0.509
20.00
0.787
10.00
0.394
C
L
TOP VIEW (COMPONENT SIDE)
BOTTOM VIEW
NOTES:
1- DIMENSIONS ARE mm/in
2- UNLESS OTHERWISE SPECIFIED, TOLERANCES ARE:
.X/(.XX) = ±0.025/(.01); XX/(.XXX) = ±0.13/(.005)
Figure 23 — PFM outline drawing
3.26
0.128
36.74
1.446
3.26
0.128
0.51
TYP
0.020
1.38
TYP
0.054
(12)
1.48
0.058
(2)
28.00
1.102
DC+
(2)
8.94
0.352
(6)
1.60
0.063
+IN
PR
SC
SG
BV
RSV
PC
(2)
22.54
0.887
(2)
(2)
16.94
0.667
14.94
0.588
(2)
(2)
11.48
0.452
12.94
0.509
+OUT
(4)
8.48
0.334
(2)
–IN
–OUT
RECOMMENDED LAND PATTERN
(COMPONENT SIDE SHOWN)
(2)
10.00
0.394
(2)
22.00
0.866
20.00
0.787
(2)
(2)
26.00
1.024
(2)
30.00
1.181
24.00
0.945
NOTES:
1- DIMENSIONS ARE mm/in
2- UNLESS OTHERWISE SPECIFIED, TOLERANCES ARE:
.X/(.XX) = ±0.025/(.01); XX/(.XXX) = ±0.13/(.005)
Figure 24 — PFM PCB land and layout information
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 13 of 14
PRELIMINARY
Warranty
Vicor products are guaranteed for two years from date of shipment against defects in material or workmanship when in
normal use and service. This warranty does not extend to products subjected to misuse, accident, or improper
application or maintenance. Vicor shall not be liable for collateral or consequential damage. This warranty is extended
to the original purchaser only.
EXCEPT FOR THE FOREGOING EXPRESS WARRANTY, VICOR MAKES NO WARRANTY, EXPRESS OR IMPLIED, INCLUDING, BUT
NOT LIMITED TO, THE WARRANTY OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
Vicor will repair or replace defective products in accordance with its own best judgement. For service under this
warranty, the buyer must contact Vicor to obtain a Return Material Authorization (RMA) number and shipping
instructions. Products returned without prior authorization will be returned to the buyer. The buyer will pay all charges
incurred in returning the product to the factory. Vicor will pay all reshipment charges if the product was defective within
the terms of this warranty.
Information published by Vicor has been carefully checked and is believed to be accurate; however, no responsibility is
assumed for inaccuracies. Vicor reserves the right to make changes to any products without further notice to improve
reliability, function, or design. Vicor does not assume any liability arising out of the application or use of any product or
circuit; neither does it convey any license under its patent rights nor the rights of others. Vicor general policy does not
recommend the use of its components in life support applications wherein a failure or malfunction may directly threaten
life or injury. Per Vicor Terms and Conditions of Sale, the user of Vicor components in life support applications assumes
all risks of such use and indemnifies Vicor against all damages.
Vicor’s comprehensive line of power solutions includes high density AC-DC
and DC-DC modules and accessory components, fully configurable AC-DC
and DC-DC power supplies, and complete custom power systems.
Information furnished by Vicor is believed to be accurate and reliable. However, no responsibility is assumed by Vicor for
its use. Vicor components are not designed to be used in applications, such as life support systems, wherein a failure or
malfunction could result in injury or death. All sales are subject to Vicor’s Terms and Conditions of Sale, which are
available upon request.
Specifications are subject to change without notice.
Intellectual Property Notice
Vicor and its subsidiaries own Intellectual Property (including issued U.S. and Foreign Patents and pending patent
applications) relating to the products described in this data sheet. Interested parties should contact Vicor's
Intellectual Property Department.
Vicor Corporation
25 Frontage Road
Andover, MA, USA 01810
Tel: 800-735-6200
Technical Support: 800-927-9474
Fax: 978-475-6715
email
Vicor Express: [email protected]
Technical Support: [email protected]
Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Power Factor Module
F3D480T20A
Rev. 1.0
Page 14 of 14
10/05
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