ncp802san6t1g ON Semiconductor, ncp802san6t1g Datasheet - Page 18

ncp802san6t1g

Manufacturer Part Number

ncp802san6t1g

Description

Highly Integrated Lithium Battery Protection Circuit For One Cell Battery Packs

Manufacturer

ON Semiconductor

Datasheet

1.NCP802SAN6T1G.pdf (23 pages)

Current page: 18 of 23
Download datasheet (135Kb)

Undervoltage Detection

pin voltage. When the VCELL voltage crosses the

undervoltage threshold (VDET2) from a high value to a

value lower than VDET2, VD2 senses an undervoltage

condition, and an external, discharge control, N−channel

MOSFET turns off by driving the DO pin to its low level.

The low level of DO is set to GND and the high level to

VCELL.

charger to the battery pack. While the VCELL voltage

remains under VDET2, charge−current can flow through the

parasitic diode of the external discharge control MOSFET.

Once the VCELL voltage rises above VDET2, the NCP802

drives DO high. Connecting a charger to the battery pack

drives the DO level high instantaneously when the VCELL

voltage is higher than VDET2. VD2 has no hysteresis.

NCP802 enters a low supply current, standby mode.

Maximum standby current equals 0.1 mA at VCELL equal

to 2.0 V. An internal pull−up disables all the device functions

and thus drastically lowers quiescent current. When the

charger connects to the battery, it pulls small levels of

current from the P− pin. This overcomes the internal pull−up

and allows the NCP802 to reset.

and release from an undervoltage condition. If the fault or

reset conditions are shorter than their respective delay times,

the NCP802 ignores that condition and stays in its previous

state.

Excess Discharge−Current/Short Circuit Detection

short circuit detector can function when the control

MOSFET’s are on. When the P− pin voltage is below the

short circuit detection voltage (VSHORT) and above the

excess discharge−current threshold (VDET3), VD3

operates. When the P− pin voltage rises higher than

VSHORT, the NCP802 enables the short circuit detector.

When either detector activates, the NCP802 turns off an

external, discharge control, N−channel, MOSFET by

driving the DO pin to its low level.

detector is internally fixed. If the P− pin, voltage level

recovers from a level between VSHORT and VDET3 within

the delay time, the discharge MOSFET stays in its high state.

Output delay time for release from excess discharge−current

detection is typically 1.2 ms. When the short circuit detector

activates, DO transitions to its low state after a delay time of

approximately 400 ms.

connected between the P− and GND pins. After VD3 or the

The undervoltage detector (VD2) monitors the VCELL

To reset the DO pin to its high level, one must connect a

After VD2 detects an undervoltage condition, the

There are internal, fixed delay times for both the detection

The excess discharge−current detector (VD3) and the

The output delay time for the excess discharge−current

There is an integrated pull−down resistor (RSHORT)

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NCP802

short circuit detector has activated; removing the cause of

that activation turns the discharge MOSFET back on. This

occurs because RSHORT pulls the P− pin, voltage level

down to the GND pin, voltage level. The NCP802 internally

disconnects RSHORT during a normal, fault−free, state. The

NCP802 only connects RSHORT if it has detected an excess

discharge−current or short circuit fault. In other words, VD3

is automatically released from excess discharge−current and

short circuit faults when the user removes the load.

detection is set shorter than the delay time for undervoltage

detection. Therefore, if VCELL voltage drops below

VDET2 during an excess discharge−current or short circuit

fault, the NCP802 detects the current fault first. This

prevents large discharge current faults from activating the

undervoltage detector and putting the NCP802 into standby

mode. Standby mode requires the charger to reset the

NCP802, while excess discharge−current and short circuit

faults only require that the fault be removed.

Excess Charge−Current Detection

possible, VD4 senses the P− pin voltage. For example, if the

user connects the battery to an inappropriate charger, excess

current can flow. Then, the P− voltage drops below the

excess charge−current threshold (VDET4). Next, the output

of CO becomes low. This prevents excess current flow into

the circuit by turning off the external MOSFET.

internally fixed. If the fault condition is within the delay time

window, the detector will not sense it and the MOSFET will

not change state. VD4 can be released by disconnecting a

charger and applying a load.

Delay Shortening Function

excess discharge−current, excess charge−current, and the

release from those detecting modes can be made shorter than

the pre−set value by forcing the VCELL voltage to the DS

pin. When one forces the specified middle range voltage to

the DS pin, the output delay circuit becomes disabled.

Therefore, under this condition, when over−charge or excess

charge current is detected, output level can be checked

without waiting for the delay.

pin and GND internally. For normal operation, the DS pin

should be at no connection state.

Zero Battery Voltage Charging

charge, minimum voltage (VST), the NCP802 drives the CO

pin high. Therefore, it allows charging for batteries as low

as zero volts.

The output delay time of excess discharge−current

When the battery pack is chargeable and discharge is also

The output delay of the excess charge−current detector is

The output delay time of over−charge, over−discharge,

A 1.3 MW pull−down resistor is connected between DS

If the charger voltage is equal or higher than the zero−volt

ncp802san6t1g ON Semiconductor, ncp802san6t1g Datasheet - Page 18

ncp802san6t1g

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