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B048K120T20 Datasheet, PDF (12/16 Pages) Vicor Corporation – VI Chip - BCM Bus Converter Module | |||
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Application Note
Parallel Operation
The BCM will inherently current share when properly
configured in an array of BCMs. Arrays may be used for
higher power or redundancy in an application.
Current sharing accuracy is maximized when the source and
load impedance presented to each BCM within an array are equal.
The recommended method to achieve matched impedances is to
dedicate common copper planes within the PCB to deliver and
return the current to the array, rather than rely upon traces of
varying lengths. In typical applications the current being
delivered to the load is larger than that sourced from the input,
allowing traces to be utilized on the input side if necessary. The
use of dedicated power planes is, however, preferable.
The BCM power train and control architecture allow
bi-directional power transfer, including reverse power
processing from the BCM output to its input. Reverse power
transfer is enabled if the BCM input is within its operating
range and the BCM is otherwise enabled. The BCMâs ability to
process power in reverse improves the BCM transient response
to an output load dump.
Thermal Management
The high efficiency of the Vâ¢I Chip results in relatively low
power dissipation and correspondingly low generation of heat.
The heat generated within internal semiconductor junctions is
coupled with low effective thermal resistances, RθJC and RθJB,
to the Vâ¢I Chip case and its Ball Grid Array allowing thermal
management flexibility to adapt to specific application
requirements (Fig. 25).
CASE 1 Convection via optional Pin Fins to air.
If the application is in a typical environment with forced
convection over the surface of the PCB and greater than 0.4"
headroom, a simple thermal management strategy is to procure
the optional Pin Fins for the Vâ¢I Chips. The total Junction-to-
Ambient thermal resistance, RθJA, of a surface mounted
Vâ¢I Chip with optional 0.25" Pin Fins is 5°C/W in 300 LFM air
flow (Fig.26). At full rated output power of 200 W, the heat
generated by the BCM is approximately 9 W (Fig.6). Therefore,
the junction temperature rise to ambient is approximately 45°C.
Given a maximum junction temperature of 125°C, a temperature
rise of 45°C allows the Vâ¢I Chip to operate at rated output
θJC = 1.1 °C/W
θJB = 2.1 °C/W
power at up to 80°C ambient temperature. At 100 W of output
power, operating ambient temperature extends to 100°C.
CASE 2âConduction to the PCB
The low thermal resistance Junction-to-BGA, RθJB, allows
use of the PCB to exchange heat from the Vâ¢I Chip,
including convection from the PCB to the ambient or
conduction to a cold plate.
For example, with a Vâ¢I Chip surface mounted on a 2" x 2"
area of a multi-layer PCB, with an aggregate 8 oz of effective
copper weight, the total Junction-to-Ambient thermal
resistance, RθJA, is 6.5°C/W in 300 LFM air flow (see
Thermal Resistance section, page 1). Given a maximum
junction temperature of 125°C and 9 W dissipation at 200 W of
output power, a temperature rise of 59°C allows the Vâ¢I Chip to
operate at rated output power at up to 66°C ambient temperature.
210
180
150
120
90
60
30
0
-40
-20
0
20
40
60
80
100
Operating Junction Temperature
Figure 24â Thermal derating curve
120
140
10
9
8
7
6
5
4
3
0
BCM with 0.25'' optional Pin Fins
100
200
300
400
500
600
Airflow (LFM)
Figure 23âThermal resistance
45 Vicor Corporation
Tel: 800-735-6200
vicorpower.com
Figure 25âJunction-to-ambient thermal resistance of BCM
with 0.25" Pin Fins (Pin Fins available as a separate item.)
Vâ¢I Chip Bus Converter
B048K120T20
Rev. 2.2
Page 12 of 16
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