ISL6255HRZ Intersil, ISL6255HRZ Datasheet - Page 13

ISL6255HRZ

Manufacturer Part Number

ISL6255HRZ

Description

IC CTRLR BATT CHRGR LI-ION 28QFN

Manufacturer

Intersil

Datasheet

1.ISL6255AHRZ.pdf (22 pages)

Specifications of ISL6255HRZ

Function

Charge Management

Battery Type

Lithium-Ion (Li-Ion), Lithium-Polymer (Li-Pol)

Voltage - Supply

7 V ~ 25 V

Operating Temperature

-10°C ~ 100°C

Mounting Type

Surface Mount

Package / Case

28-VFQFN Exposed Pad

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Meier Automation Equipment Co., Limited

Part Number:

ISL6255HRZ

Manufacturer:

INTERSIL

Quantity:

20 000

Current page: 13 of 22
Download datasheet (652Kb)

Theory of Operation

Introduction

The ISL6255, ISL6255A includes all of the functions

necessary to charge 2 to 4 cell Li-Ion and Li-polymer

batteries. A high efficiency synchronous buck converter is

used to control the charging voltage and charging current up

to 10A. The ISL6255, ISL6255A has input current limiting

and analog inputs for setting the charge current and charge

voltage; CHLIM inputs are used to control charge current

and VADJ inputs are used to control charge voltage.

The ISL6255, ISL6255A charges the battery with constant

charge current, set by CHLIM input, until the battery voltage

rises up to a programmed charge voltage set by VADJ input;

then the charger begins to operate at a constant voltage

charge mode. The charger also drives an adapter isolation P-

channel MOSFET to efficiently switch in the adapter supply.

ISL6255, ISL6255A is a complete power source selection

controller for single battery systems and also aircraft power

applications. It drives a battery selector P-channel MOSFET

to efficiently select between a single battery and the adapter.

It controls the battery discharging MOSFET and switches to

the battery when the AC adapter is removed, or, switches to

the AC adapter when the AC adapter is inserted for single

battery system.

The EN input allows shutdown of the charger through a

command from a micro-controller. It also uses EN to safely

shutdown the charger when the battery is in extremely hot

conditions. The amount of adapter current is reported on the

ICM output. Figure 14 shows the IC functional block diagram.

The synchronous buck converter uses external N-channel

MOSFETs to convert the input voltage to the required

charging current and charging voltage. Figure 15 shows the

ISL6255, ISL6255A typical application circuit with charging

current and charging voltage fixed at specific values. The

typical application circuit shown in Figure 16 shows the

ISL6255, ISL6255A typical application circuit which uses a

micro-controller to adjust the charging current set by CHLIM

input for aircraft power applications. The voltage at CHLIM

and the value of R1 sets the charging current. The DC/DC

converter generates the control signals to drive two external

N-channel MOSFETs to regulate the voltage and current set

by the ACLIM, CHLIM, VADJ and CELLS inputs.

The ISL6255, ISL6255A features a voltage regulation loop

(VCOMP) and two current regulation loops (ICOMP). The

VCOMP voltage regulation loop monitors CSON to ensure

that its voltage never exceeds the voltage and regulates the

battery charge voltage set by VADJ. The ICOMP current

regulation loops regulate the battery charging current

delivered to the battery to ensure that it never exceeds the

charging current limit set by CHLIM; and the ICOMP current

regulation loops also regulate the input current drawn from

the AC adapter to ensure that it never exceeds the input

ISL6255, ISL6255A

current limit set by ACLIM, and to prevent a system crash

and AC adapter overload.

PWM C o ntrol

The ISL6255, ISL6255A employs a fixed frequency PWM

current mode control architecture with a feed-forward

function. The feed-forward function maintains a constant

modulator gain of 11 to achieve fast line regulation as the

buck input voltage changes. When the battery charge

voltage approaches the input voltage, the DC/DC converter

operates in dropout mode, where there is a timer to prevent

the frequency from dropping into the audible frequency

range. It can achieve duty cycle of up to 99.6%.

To prevent boosting of the system bus voltage, the battery

charger operates in standard-buck mode when CSOP-

CSON drops below 4.25mV. Once in standard-buck mode,

hysteresis does not allow synchronous operation of the

DC/DC converter until CSOP-CSON rises above 12.5mV.

An adaptive gate drive scheme is used to control the dead

time between two switches. The dead time control circuit

monitors the LGATE output and prevents the upper side

MOSFET from turning on until LGATE is fully off, preventing

cross-conduction and shoot-through. In order for the dead

time circuit to work properly, there must be a low resistance,

low inductance path from the LGATE driver to MOSFET

gate, and from the source of MOSFET to PGND. The

external Schottky diode is between the VDDP pin and BOOT

pin to keep the bootstrap capacitor charged.

Setting the Battery Regulation Voltage

The ISL6255, ISL6255A uses a high-accuracy trimmed

band-gap voltage reference to regulate the battery charging

voltage. The VADJ input adjusts the charger output voltage,

and the VADJ control voltage can vary from 0 to VREF,

providing a 10% adjustment range (from 4.2V-5% to

4.2V+5%) on CSON regulation voltage. An overall voltage

accuracy of better than 0.5% is achieved.

The per-cell battery termination voltage is a function of the

battery chemistry. Consult the battery manufacturers to

determine this voltage.

• Float VADJ to set the battery voltage V

• Connect VADJ to VREF to set 4.41V × number of cells,

• Connect VADJ to ground to set 3.99V × number of the

So, the maximum battery voltage of 17.6V can be achieved.

Note that other battery charge voltages can be set by

connecting a resistor divider from VREF to ground. The resistor

divider should be sized to draw no more than 100µA from

VREF; or connect a low impedance voltage source like the D/A

converter in the micro-controller. The programmed battery

voltage per cell can be determined by the following equation:

CELL

number of the cells,

cells.

. 0

175

VADJ

3.99

CSON

= 4.2V ×

May 23, 2006

FN9203.2

ISL6255HRZ Intersil, ISL6255HRZ Datasheet - Page 13

ISL6255HRZ

Specifications of ISL6255HRZ

Available stocks

Related parts for ISL6255HRZ