Figure 16-1 shows a simplified application schematic for a 14-series battery pack, using the BQ769142
together with an external secondary protector, a host microcontroller, and a communications
transceiver. This configuration uses CHG and DSG FETs in series, together with high-side
PFET devices used to implement precharge and predischarge functionality. See the following
implementation considerations:
The external NPN BJT used for the REGIN
preregulator can be configured with its collector routed either to the cell battery stack
or the middle of the protection FETs.
A diode is recommended in the drain
circuit of the external NPN BJT, which avoids reverse current flow from the BREG pin
through the BJT base to collector in the event of a pack short circuit. This diode can be
a Schottky diode if low voltage pack operation is needed, or a conventional diode can be
used otherwise.
A series diode is recommended at the BAT
pin, together with a capacitor from the pin to VSS. These components allow the device to
continue operating for a short time when a pack short circuit occurs, which may cause the
PACK+ and top-of-stack voltages to drop to approximately 0 V. In this case, the diode
prevents the BAT pin from being pulled low with the stack, and the device will continue to
operate, drawing current from the capacitor. Generally operation is only required for a
short time, until the device detects the short circuit event and disables the DSG FET. A
Schottky diode can be used if low voltage pack operation is needed, or a conventional
diode can be used otherwise.
The diode in the BAT connection and the
diode in the BJT collector should not be shared, since then the REG0 circuit might
discharge the capacitor on BAT too quickly during a short circuit event.
The recommended voltage range on the VC0
to VC4 pins extends to –0.2 V. This can be used, for example, to measure a differential
voltage that extends slightly below ground, such as the voltage across a second sense
resistor in parallel with that connected to the SRP and SRN pins.
If a system does not use high-side
protection FETs, then the PACK pin can be connected through a series 10-kΩ resistor to the
top of stack. The LD pin can be connected to VSS. In this case, the LD pin can also be
controlled separately, in order to wake the device from SHUTDOWN mode, such as through
external circuitry which holds the LD pin at the voltage of VSS while the device stays in
SHUTDOWN, and to be driven above a voltage of VWAKEONLD in order to wake from
SHUTDOWN.
TI recommends using 100 Ω resistors in
series with the SRP and SRN pins, and a 100 nF with optional 100 pF differential filter
capacitance between the pins for filtering. The routing of these components, together with
the sense resistor, to the pins should be minimized and fully symmetric, with all
components recommended to stay on the same side of the PCB with the device.
Optional
0.1-μF
filter capacitors can be added for additional noise filtering at each sense input pin to
VSS.
Due to thermistors often being attached
to cells and possibly needing long wires to connect back to the device, it may be helpful
to add a capacitor from the thermistor pin to the device VSS. However, it is important
not
to
use too
large of a value of capacitor, since this
affects
the settling time when the thermistor is biased and measured periodically. A rule of thumb
is to keep the time constant of the circuit < 5% of the measurement time. When
Settings:Configuration:Power Config[FASTADC] = 0, the measurement time
is approximately 3 ms, and with [FASTADC] = 1 the measurement time is halved
to approximately 1.5 ms. When using the
18-kΩ
pullup resistor with the thermistor, the time constant
is
generally
less than
(18 kΩ) × C, so a capacitor less than 4 nF is recommended. When using the 180-kΩ pullup
resistor, the capacitor should be less than 400 pF.
The integrated charge pump generates a
voltage on the CP1 capacitor, requiring approximately 60 ms to charge up to approximately
11 V when first enabled, when using the recommended
470-nF
capacitor value. When the CHG or DSG drivers are enabled, charge redistribution occurs
from the CP1 capacitor to the CHG and DSG capacitive FET loads. This
generally
results
in a brief drop in the voltage on CP1, which is then replenished by the charge pump. If
the FET capacitive loading is large, such that at FET
turnon the
voltage on CP1 drops below an acceptable level for the application, then the value of the
CP1 capacitor can be increased. This has the drawback of requiring a longer startup time
for the voltage on CP1 when the charge pump is first powered on, and so should be
evaluated to ensure it is acceptable in the system. For example, if the CHG and DSG FETs
are enabled simultaneously and their combined gate capacitance is approximately 400 nF,
then changing CP1 to a value of 2200 nF will result in the 11-V charge pump level dropping
to approximately 9 V, before being restored to the 11-V level by the charge pump.
Figure 16-2 and Figure 16-3 show a full schematic of a basic monitor circuit based on the BQ769142 for a 14-series
battery pack. The BQ76952 EVM also provides a good reference design for BQ769142, noting
that the VC12 - VC16 connections in the BQ76952 EVM need to be modified as shown in Figure 16-1.