JAJSL83 データシート

JAJSL83D August 2020 – September 2022 BQ79612-Q1 , BQ79614-Q1 , BQ79616-Q1

PRODUCTION DATA

パッケージ・オプション

メカニカル・データ（パッケージ｜ピン）

PAP|64
- MPQF071C

サーマルパッド・メカニカル・データ

PAP|64
- PPTD012N

発注情報

10.2.1.2.2 BAT and External NPN

Related Pins	Components	Value	Description
BAT	Filter resistor	30 Ω	Single-ended RC filter, recommended values must be used for hot-plug performance.
BAT	Filter capacitor	10 nF/100 V Can use lower voltage rating based on module size
NPNB	NPN (Q1)	Collector–emitter breakdown voltage 80 V to 100 V, but can use lower rating based on module size Power rating ≥ 1 W Gain > 80 at the expected load current Current handling >100 mA	The external NPN is used to form a pre-regulation circuit to provide a 6-V (typical) input to the LDOIN pin. The voltage rating of the NPN can be optimized by the following equation: NPN voltage rating = Max VModule – Min VLDOIN + Margin Where: Max VModule = maximum module voltage with fully charged cells Min VLDOIN = the minimum spec of the VLDOIN parameter Margin = system transient voltage + design margin per application requirement
	Resistor on external NPN collector (R_NPN)	Various based on module voltage	The resistor has a couple purposes: (a) For an RC filter for the NPN pre-regulation circuit (b) Share the thermal dissipation with the NPN
	Capacitor on external NPN collector	0.22 μF/100 V Can use lower voltage rating based on module size	The capacitor forms the RC filter for the NPN pre-regulation circuit The capacitor rating is based on peak voltage spike seen on the module. For smaller module size, <100-V rated capacitor can be used. System designer selects the optimized voltage-rated capacitor per their system tolerance and requirements.

To reduce the power rating needed for the external NPN (Q1), system designer can put power resistors on the NPN collector to create IR drop from the module voltage (VModule). Figure 10-3 shows the current paths to power the BQ7961x device.

Typical ISTARTUP current i.e. Inrush startup current when device enters from SHUTDOWN to ACTIVE is 20mA for TI recommended components. This current is sum of IBAT + ILDOIN, and is dependent on PCB board components and layout, so recommend user to characterize on their end.

Figure 10-3 Power Consumption Paths

To ensure there is sufficient headroom to maintain 6 V (typical) regulated voltage on LDOIN pin, system designer ensures VCollector has ≥ 8 V at any time with the assumption of about 2-V drop across the NPN.

Hence, maximum allowable R_NPN value = ((Min VModule) – (VCollector)) / (Max peak current)

Where:

Min VModule: based on module size and minimum cell voltage per application

VCollector: 8 V with the assumption of about 2-V drop across NPN

Max peak current: highest operation current, which is the active current with all functions turned on. Note that different communication isolation components (for example, capacitor isolation versus transformer, or the type of transformer) contribute different loading to the total power consumption.

Power the device separately from the to of the battery stack:

The device is designed to be powered by the battery stack. If there is a need to power the device from a separately source such as in Figure 10-4, the following relationship between the voltage on the BAT pin and the highest VC pin voltage (with respected to ground): BAT voltage >= (0.5 * highest VC voltage) + 2

For example, if the device is connected to a 14S module with max cell voltage of 4.2V/cell, the highest VC pin is VC14, and the highest VC14 voltage is (4.2V * 14) = 58.8V. If the BAT pin is powered separately, BAT voltage must be >= 31.4V.

Similarly, if BBP/N channel is connected above the highest cell stack, the BBP pin will has the highest voltage (with respected to ground) than the VC pins. In this scenario, VBAT >= [(VBBP-2.5) * 0.84] + 4.5.The requirement applies when BAT is power separately and it is to ensure proper operation of the internal level shifter. Fail to maintain the voltage relationship will increase the ADC measurement error on the VC and BB channels.

Figure 10-4 Separate Power Source to BAT