TI BQ24450DWTR

bq24450
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INTEGRATED CHARGE CONTROLLER FOR LEAD-ACID BATTERIES
•
•
•
FEATURES
1
•
•
•
Regulates Both Voltage and Current During
Charging
Precision Temperature-Compensated
Reference:
– Maximizes Battery Capacity Over
Temperature
– Ensures Safety While Charging Over
Temperature
Optimum Control to Maximize Battery Capacity
and Life
Supports Different Configurations
Minimum External Components
Available in 16-Pin PDIP and SOIC (DW)
APPLICATIONS
•
•
•
•
Emergency Lighting Systems
Security and Alarm Systems
Telecommunication Backup Power
Uninterruptible Power Supplies
DESCRIPTION
The bq24450 contains all the necessary circuitry to optimally control the charging of valve-regulated lead-acid
batteries. The IC controls the charging current as well as the charging voltage to safely and efficiently charge the
battery, maximizing battery capacity and life. Depending on the application, the IC can be configured as a simple
constant-voltage float charge controller or a dual-voltage float-cum-boost charge controller.
The built-in precision voltage reference is especially temperature-compensated to track the characteristics of
lead-acid cells, and maintains optimum charging voltage over an extended temperature range without using any
external components. The ICs low current consumption allows for accurate temperature monitoring by minimizing
self-heating effects.
The IC can support a wide range of battery capacities and charging currents, limited only by the selection of the
external pass transistor. The versatile driver for the external pass transistor supports both NPN and PNP types
and provides at least 25mA of base drive.
In addition to the voltage- and current-regulating amplifiers, the IC features comparators that monitor the
charging voltage and current. These comparators feed into an internal state machine that sequences the charge
cycle. Some of these comparator outputs are made available as status signals at external pins of the IC. These
status and control pins can be connected to a processor, or they can be connected up in flexible ways for
standalone applications.
TYPICAL APPLICATION SCHEMATIC
RISNS
QEXT
VRLA
Battery
External
Supply
3
2
ISNSP ISNSM
5
IN
1
ISNS
16
4
RT
15
DRVC DRVE
PRE-CHG 11
IFB
RA
CE 12
8
9
RB
VFB 13
bq24450
BSTOP
STAT1 10
STAT2
GND
COMP
6
14
PGOOD 7
RD
RC
CCOMP
A dual-level Float-cum-Boost Charger with Pre-Charge
1
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas
Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2009, Texas Instruments Incorporated
bq24450
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These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
ORDERING INFORMATION
DEVICE PACKAGE
PACKING
ORDERABLE PART NUMBER
MARKING
PDIP (N)
Tube of 25
bq24450N
bq24450N
Tube of 50
bq24450D
bq24450D
Reel of 2500
bq24450DR
bq24450D
SOIC (D)
ABSOLUTE MAXIMUM RATINGS (1)
(2) (3)
over operating free-air temperature range (unless otherwise noted)
Input Voltage
Voltage
VALUE
UNIT
IN
–0.3 to 40
V
PGOOD, STAT1, STAT2, ISNS
–0.3 to 40
V
VFB, IFB, ISNSP, ISNSM
–0.3 to 40
V
BSTOP
–0.3 to 40
V
PRE-CHG (with respect to IN)
–32
V
ISNS
80
mA
STAT1, STAT2, PGOOD
20
mA
Output Current
PRE-CHG
–40
mA
Input Current
DRVC
80
mA
Output Current
DRVE
–80
mA
Input Current
Power Dissipation at TA = 25°C
1000
mW
Junction temperature, TJ
–40 to 150
°C
Storage temperature, TSTG
–65 to 150
°C
(1)
(2)
(3)
Stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. These are stress ratings
only, and functional operation of the device at these or any other conditions beyond those indicated under recommended operating
conditions is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
All voltage values are with respect to the ground terminal (pin 6) unless otherwise noted.
Positive currents are into, and negative currents out of, the specified terminal.
RECOMMENDED OPERATING CONDITIONS
over operating free-air temperature range (unless otherwise noted)
VIN
IN voltage range
ISTAT1, ISTAT2, IPGOOD
Input current, open-collector status pins
IISNS
Input current, open-collector ISNS comparator output
TJ
Junction Temperature
2
MIN
MAX
5
40
V
5
mA
25
mA
70
°C
–40
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UNITS
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ELECTRICAL CHARACTERISTICS
Over junction temperature range –40°C ≤ TJ ≤ 70°C, VIN = 10V, TJ = TA. (Positive currents are into, and negative currents out
of, the specified terminal)
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNIT
INPUT
UVLO
Input power detected threshold
VIN increasing from 0V to 5V
4.5
4.8
V
VHYS-UVLO
Hysteresis on UVLO
VIN decreasing from 5V to 0V
4.2
200
300
mV
VIN = 10V
1.6
3.3
IIN
Operating current
VIN = 40V
1.8
3.6
VIN = 40V, TA = –40°C to 85°C
1.8
4
2.300
2.325
mA
INTERNAL REFERENCE (VREF)
VREF
Reference voltage level
dVREF/dT
Temperature coefficient of VREF
ΔVREF
Line regulation of VREF
Measured as regulating level on VFB pin
when device is in FLOAT mode.
TJ = 25°C
2.275
–3.5
VIN = 5V to 40V
3
V
mV/°C
8
mV
VOLTAGE AMPLIFIER
IVFB
Input bias current
VVFB = 2.30V
AOV
Open-loop gain
Driver current = 1mA
VO
Output voltage swing (above GND or below VIN)
–500
–200
50
65
nA
dB
200
mV
CURRENT LIMIT AMPLIFIER
IIFB
Input bias current
VILIM
Threshold voltage (wrt VIN)
ΔVILIM
Sensitivity of VILIM to VIN
225
VIN = 5V to 40V
0.2
1
µA
250
275
mV
0.03
0.25
%/V
2
2.2
DRIVER TRANSISTOR
VCE
Minimum collector to emitter differential
VDRVC = VIN, IDRVE = 10mA
IDRVE-MAX
Maximum output current
VDRVC – VDRVE = 2 V
V
25
40
mA
–40
–25
mA
PRE-CHG
IPRE
Maximum output current VPRE = VIN - 3V
VPRE
Maximum output voltage (VIN – VPRE-CHG)
IPRE = –10mA
VPRE-REV
PRE-CHG reverse hold-off voltage
VIN = 0 V, IPRE = –10µA
2
2.6
V
6.3
7
V
1.01
ENABLE COMPARATOR
VTH-CE
Threshold voltage (x VREF)
0.99
1.00
ICE
Input bias current
–500
–200
V/V
nA
CURRENT SENSE COMPARATOR
IIB-ISNS
Input bias current
IOS-ISNS
Input offset current
100
500
10
200
VISNS
Threshold voltage (VISNSP – VISNSM)
nA
25
30
mV
ΔVISNS/ΔVIN
Threshold sensitivity to VIN
ΔVISNS/ΔVCM
Threshold sensitivity to common-mode voltage
VIN = 5V to 40V
0.05
0.35
%/V
VCM = 2V to VIN
0.05
0.35
IISNS
Maximum sink current, ISNS pin
VISNS = 2 V
%/V
25
40
VISNS-SAT
Saturation voltage, ISNS pin
IISNS = 10 mA
mA
200
450
mV
20
nA
VOLTAGE SENSE COMPARATOR
VVSNS
Threshold voltage (x VREF)
L1 = RESET
L1 = SET
0.94
0.95
0.96
0.895
0.90
0.910
1
1.3
INPUT LOGIC LEVELS – BSTOP
VTH-BS
Threshold voltage
IPU-BS
Internal pull-up current
0.7
VBSTOP = VTH-BS
V
µA
10
OUTPUT LOGIC LEVELS – STAT1, STAT2, PGOOD
ISINK-MAX
Maximum sink current
VSAT
Output saturation voltage
Ilkg
Leakage current
VPIN = 2V, output transistor ON
2.5
5
mA
ISINK = 1.6 mA
250
450
mV
ISINK = 50 µA
30
50
mV
1
3
µA
VPIN = 40V, output transistor OFF
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IFB
ISNSP ISNSM
DRVC
DRVE
12W
Driver
+
25 mV
Q1
VIN
ISNS
+
250mV
COMP
Current Sense
Comparator
Current Limit
VREF
Voltage Loop
VIN
Q5
VREF
IN
VIN
Voltage Reference
o
2.3V at 25 C
-3.5 mV/C
VFB
VVFB
PRE-CHG
Enable Comparator
UVLO
CE
Q2
VIN
Q3
VREF
Q4
PGOOD
Q7
VVFB
S1
Voltage Sense
Comparator
S0
0.95VREF
0.90VREF
STAT1
Q8
STAT2
R
R
Q
L1
L2
S
BSTOP
Q
Q9
S
GN
Figure 1. Simplified Block Diagram
4
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PIN FUNCTIONS
PIN #
NAME
I/O
DESCRIPTION
1
ISNS
O
Output of the current-sense comparator. Open-Collector.
2
ISNSM
I
Negative input of the current-sense comparator.
3
ISNSP
I
Positive input of the current-sense comparator.
4
IFB
I
Input for the current-regulating loop. External resistor between IN and IFB sets the
charging current value.
5
IN
I
Supply voltage pin. Connect to external DC source.
6
GND
–
Ground terminal.
7
PGOOD
O
Open-collector output, indicates supply status at IN pin. Active low.
8
BSTOP
I
Control input. Taking this pin from low to high transitions the charger from Boost Mode
to Float Mode. Internally pulled up through a 10µA current source.
9
STAT2
O
10
STAT1
O
11
PRE-CHG
O
Can be used to trickle-charge the battery till its voltage rises to a safe value. PRE-CHG
will source current as long as the control voltage on the CE pin is below VREF. If
using, connect to battery pack through external resistor.
12
CE
I
Charge enable control. If the voltage on the CE pin is below VREF, the driver transistor
will be off and the PRE-CHG pin will source current.
13
VFB
I
Voltage feedback pin. Connect to battery through external resistive divider.
14
COMP
I/O
Compensation terminal for voltage loop. Connect a capacitor from this pin to GND.
15
DRVE
O
Emitter of the internal (NPN) driver transistor.
16
DRVC
I
Collector of the internal (NPN) driver transistor.
Open-collector status outputs. See table below.
PINOUT
STAT1
STAT2
Hi-Z
Hi-Z
CONDITION
Float Mode
On
Hi-Z
Bulk Charge
On
On
Boost Mode
DW PACKAGE
(TOP VIEW)
ISNS
1
16 DRVC
ISNSM
2
15 DRVE
ISNSP 3
14 COMP
IFB
4
13 VFB
IN
5
12 CE
GND
6
11 PRE-CHG
PGOOD
7
10 STAT1
BSTOP 8
9 STAT2
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TYPICAL OPERATING PERFORMANCE
Compensated Voltage Reference
vs
Temperature
2.6
2.5
VREF - Voltage Reference − V
VIN = 10V
Specified
Error Band
2.4
2.3
2.2
Specified
Error Band
2.1
2
-40 -30 -20 -10
0
10 20
30 40
50 60
70
o
T − Temperature − C
Figure 2. -
6
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DETAILED FUNCTIONAL DESCRIPTION
The bq24450 contains all the necessary circuitry to optimally control the charging of sealed lead-acid batteries.
The IC controls the charging current as well as the charging voltage to safely and efficiently charge the battery,
maximizing battery capacity and life. Depending on the application, the IC can be configured in various ways:
examples are a constant-voltage float charger, a dual-voltage float-cum-boost charger or a dual step current
charger.
Only an external pass transistor and minimum number of external passive components are required along with
the IC to implement a charger for sealed lead-acid batteries. The IC's internal driver transistor Q1 (see Figure 1)
supports NPN as well as PNP pass transistors, and provides enough drive current (25mA specified) to support a
wide range of charging rates.
The driver transistor is controlled by a voltage regulating loop and a current limiting-limiting loop (see Figure 1).
The current-limiting loop reduces drive when the voltage between the IN pin and the IFB pin increases towards
VILIM (250mV typical). The voltage regulating loop tries to maintain the voltage on the VFB pin at VREF. Together,
these two loops constitute a current-limited precision constant-voltage system, which is the heart of any lead-acid
charger. The voltage regulating amplifier needs an external compensation circuit which depends on the type of
external pass transistor (see Application Information section).
An important feature of the bq24450 is the precision reference voltage. The reference voltage is specially
temperature compensated to track the temperature characteristics of lead-acid cells. Additionally, the IC operates
with low supply current, only 1.6mA, minimizing on-chip dissipation and permitting the accurate sensing of the
operating environmental temperature by avoiding self-heating effects. To take full advantage of the
temperature-compensated reference, the IC should be in the same thermal environment as the battery.
An undervoltage lock-out circuit is also provided (see Figure 1). This circuit disables the driver transistor as long
as the input voltage is below UVLO (4.5V typical). The UVLO circuit also drives an open-collector output
PGOOD.
Voltage-sense and current-sense comparators are available in the IC. The current-sense comparator is
uncommitted. Its open-collector output is OFF when the difference between the ISNSP and ISNSM pins is less
than VISNS (25mV typical), and ON when the difference is more than VISNS. Depending on the application, this
comparator may be used to switch to float charging after the boost phase is over. The voltage sense comparator
can be used to sense the voltage level of the battery to initiate a new charge cycle.
Latches L1 and L2 constitute a state-machine to control the charging sequence. The internal inputs to the
state-machine come from the UVLO circuit and the voltage-sense comparator. One external input is provided,
the BSTOP pin. The outputs of the L1 and L2 latches are available at the STAT1 and STAT2 pins. The BSTOP
pin is internally pulled up through a 10µA current source. The states of the state-machine are:
Q(L1)
Q(L2)
STAT1
STAT2
Condition
State #
LOW
HIGH
ON
OFF
Bulk Charge
State 1
LOW
LOW
ON
ON
Boost Mode
State 2
HIGH
HIGH
OFF
OFF
Float Mode
State 3
A small bias current source is available at the PRE-CHG pin to provide pre-charge to deeply discharged
batteries. The PRE-CHG pin sources current when the voltage at the CE pin is below VREF. Driver transistor Q1
is turned OFF when the PRE-CHG current is ON.
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DETAILED OPERATION AND APPLICATION INFORMATION
A Simple Dual-Level Float-Cum-Boost Charger
Figure 3 shows the bq24450 configured as a simple dual-level float-cum-boost charger. Figure 4 shows the
sequence of events that occur in a normal charge cycle. At (1) in Figure 4, power is switched ON. As long as the
input voltage VIN is below the undervoltage lockout threshold UVLO, Q2 is ON, disabling the driver transistor Q1.
As the input voltage VIN ramps up and rises above UVLO Q2 turns OFF. This enables Q1 and thus the external
transistor QEXT. At the same time, Q7 turns ON, latch L1 is forced to RESET and latch L2 is SET (see Figure 1
for the internals of the Charging State Logic).
The voltage regulating amplifier tries to force the voltage at the VFB pin to VREF by turning Q1 and thus QEXT fully
ON, but the current limiting amplifier limits the charging current ICHG to IMAX-CHG such that the voltage across
RISNS is VILIM – 250mV typical. Thus IMAX-CHG is given by:
IMAX-CHG = VILIM ÷ RISNS
As ICHG flows into the battery, the battery terminal voltage increases. The voltage at the VFB pin is the battery
voltage scaled by the resistive divider formed by RA and RB//RC (because Q8 is ON). At (3), the voltage on the
VFB pin exceeds 0.95VREF, and the output of the voltage sense comparator goes HIGH. This forces L2 to
RESET, and STAT2 turns ON. The battery voltage VBI at this point when STAT2 indicates boost is given by:
VBI = 0.95VREF × A + RB//RC) ÷ RB//RC
Other than STAT2 changing state at this point, there is no externally observable change in the charging
conditions. IMAX-CHG continues to flow into the battery.
RISNS
VBAT
QEXT
External
Supply
ICHG
ISNSP
ISNSM
3
IFB
2
DRVC
4
VRLA
Battery
DRVE
16
15
RA
ISNS
1
Q1
250mV
14
+
+
25mV
Q6
COMP
VREF
13
Q5
11
VFB
RB
RC
VREF
IN
5
Voltage
Reference
Q2
VIN
12
Q3
VREF
Q4
CE
Connect
to IN
7
Q7
10
BSTOP
8
STAT1
Q8
0.95VREF
Charging State Logic
9
Q9
0.90VREF
VVFB
6
GND
Figure 3.
8
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As charging proceeds, the voltage at the VFB pin increases further to VREF. At this point, the voltage regulating
amplifier prevents the voltage at the VFB pin from rising further, maintaining the battery voltage at VBOOST. [(4) in
Figure 3].
VBOOST = VREF × A + RB//RC) ÷ RB//RC
ICHG keeps flowing into the battery. As the battery approaches full charge, the current into the battery decreases,
while the battery terminal voltage is maintained at VBOOST.
At (5), the charging current ICHG reduces to a value ITAPER such that the voltage across RISNS becomes less than
VISNS (25mV typical)
ITAPER = VISNS ÷ RISNS
Q6 at the output of the current sense comparator turns OFF. The internal current source pulls the BSTOP pin
HIGH, latch L1 is forced to SET, in turn forcing L2 to SET. The reference voltage on the voltage sense
comparator is now 0.9VREF. STAT1 turns OFF, and the voltage on the battery settles to:
VFLOAT = VREF × A + RB) ÷ RB
As long as the peak load current is less than IMAX-CHG, it will be supplied by QEXT, and the voltage across the
battery will be maintained at VFLOAT. But if the peak load current exceeds IMAX-CHG, the battery will have to
provide the excess current, and the battery terminal voltage will drop. Once it drops below 0.9VREF, at (6) in
Figure 3, a new charge cycle is initiated. The battery voltage VBAT at this point, VRCH, is given by:
VRCH = 0.9VREF × A + RB) / RB
1
3
2
4
5
6
7
VUVLO
VIN
IMAX-CHG
ITAPER
ICHG
VBOOST
VBI
VFLOAT
VRCH
VBAT
PGOOD Q7
OFF
ON
ISNS Q6
OFF ON
ON
OFF
OFF
ON
STAT1 Q8
ON
ON
OFF
OFF
ON
STAT2 Q9
OFF
ON
OFF
STATE #
STATE #1
ON
STATE #2
OFF
STATE #3
#1
ON
#2
Figure 4.
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An Improved Dual-Level Float-Cum-Boost Charger with Pre-Charge
The problem with the charger circuit shown in Figure 3 is that even with deeply discharged batteries, charging
starts at full current level IMAX-CHG. This can sometimes be hazardous, resulting in out-gassing from the battery.
The bq24450 can be configured to pre-charge the battery till the voltage levels rise to levels safe enough to
permit charging at IMAX-CHG.
In the circuit of Figure 5, the CE pin is used to detect the battery voltage. As long as the voltage at the CE pin is
below VREF, the enable comparator turns ON Q3 and Q4. This turns OFF Q1 and turns ON Q5, permitting a
pre-charge current IPRE to flow from the PRE-CHG pin through RT into the battery.
IPRE = (VIN – VBAT) ÷ RT
Once the battery voltage rises above a safe threshold VTH at (2) in Figure 6, the enable comparator turns OFF
Q3 and Q4, thus turning OFF Q5 and enabling Q1. QEXT then provides IMAX-CHG, and the circuit after this
performs as described before.
VTH = VREF × A + RB + RC//RD) ÷ B + RC//RD)
RISNS
I
VBAT CHG
QEXT
VRLA
Battery
External
Supply
ISNSM
ISNSP
3
IFB
2
DRVC
4
DRVE
RA
15
16
RT
ISNS
1
14
+
+
25mV
Q6
COMP
Q1
250mV
VREF
13
Q5
11
VFB
RB
PRE-CHG RC
VREF
IN
5
Voltage
Reference
12
Q2
VIN
CE
Q3
VREF
Q4
7
Q7
10
8
BSTOP
STAT1
RD
Q8
0.95VREF
Charging State Logic
9
Q9
0.90VREF
VVFB
6
GND
Figure 5.
10
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1
2
VIN
IMAX-CHG
ICHG
ITAPER
IPRE
VBOOST
VBI
VFLOAT
VRCH
VTH
VBAT
Figure 6.
Further Improvements to the Circuit of Figure 5
In applications where the load current is very low, the current through the VBAT voltage divider can be a
non-negligible proportion of the load current. Current flowing back thorough QEXT when the input power is
removed constitutes another drainage path. The modifications in Figure 7 fix both these issues.
The addition of DEXT (see Figure 7) fixes the reverse current problem. Returning the voltage feedback divider
chain to the PGOOD pin instead of to GND ensures that the divider does not draw any current when the input
supply is not present. (When sinking 50µA, the saturation voltage of the PGOOD transistor is typically only
30mV).
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RISNS
DEXT
QEXT
ICHG
VBAT
External
Supply
ISNSP
ISNSM
3
ISNS
IFB
2
DRVC
4
1
RT
15
COMP
Q1
250mV
14
+
+
25mV
Q6
RA
DRVE
16
VRLA
Battery
VREF
13
Q5
RB
VFB
11
PRE-CHG
RC
VREF
IN
Voltage
Reference
5
12
Q2
VIN
CE
Q3
VREF
Q4
7
Q7
10
8
BSTOP
STAT1
RD
Q8
0.95VREF
Charging State Logic
9
Q9
0.90VREF
VVFB
6
GND
Figure 7.
Changing the value of ITAPER for a given IMAX-CHG
In the examples above, ITAPER is 10% of IMAX-CHG, because VILIM is 250mV and VISNS is 25mV (typical values),
and the same resistor is used for both, the taper comparator and the current-loop amplifier. In most applications,
setting ITAPER to 10% of IMAX-CHG is perfectly fine. But if, for some reason, a different value of ITAPER is required, it
can be achieved, as shown in Figure 8(a) and Figure 8(b).
RISNS1
RISNS1
RISNS2
RISNS2
QEXT
QEXT
ISNSP
IN
5
ISNSM
3
2
IFB
4
IN
DRVC
16
ISNSP
5
IFB
3
Figure 8a
4
ISNSM
2
DRVC
16
Figure 8b
IMAX-CHG = VILIM ¸ (RISNS1 + RISNS2 )
IMAX-CHG = VILIM ¸ RISNS1
ITAPER = VISNS ¸ RISNS2
ITAPER = VISNS ¸ (RISNS1 + RISNS2 )
Figure 8.
12
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Selecting the External Pass Transistor
All the examples so far have used a PNP transistor for the external pass element. But the driver transistor in the
bq24450 can be configured to drive many different types of pass transistors. This section will look at some of the
different configurations that are possible. In all configurations, though, these factors hold:
1. The external pass device must have sufficient voltage rating for the application, and must have the current
and power handling capabilities to charge at the desired rate at the maximum input to output differential in
the application.
2. The device must have enough current gain at the required charging current to keep the drive current below
25mA.
The choice of the pass device and the configuration of the internal driver transistor have an effect on the
following:
1. The minimum and maximum practical charging current.
2. The open-loop gains of the current and voltage loops, and hence the value of the compensation capacitor at
the COMP pin. In battery charging applications, dynamic response is not a requirement, and the values of
CCOMP given below should give stable operation under all conditions.
3. The IC's power dissipation and thus its self-heating. The IC typically has a thermal resistance of 100°C/W.
An external resistance RP can be added to share some of the power dissipation and reduce the IC's
self-heating.
4. The minimum differential voltage ΔV (from the input to the battery) required to operate.
The next section addresses a few topologies, and gives values for the charge current range, the minimum input
to output differential ΔV, power dissipation PD in the IC, RP and CCOMP for each of the topologies. (In the
expressions below, hFE is the current gain of the external transistor).
Common-Emitter PNP
IMAX-CHG range:
25mA to 1000mA
Minimum ΔV:
0.5V
VIN
RP = (VIN(MIN) – 2.0V) ÷ IMAX-CHG × hFE(MIN)
PD = (VIN(MAX) – 0.7V) ÷ hFE × IMAX-CHG – (IMAX-CHG)2 ÷ (hFE)2 × RP
CCOMP = 0.1 µF
VOUT
QEXT
DRVC
16
Q1
DRVE
15
RP
PNP in a Quasi-Darlington With Internal Driver
IMAX-CHG range:
25mA to 1000mA
Minimum ΔV:
2V
VIN
RP = (VIN(MIN) – VOUT(MAX) – 1.2 V) ÷ IMAX-CHG × hFE(MIN)
PD = (VIN(MAX) – VOUT – 0.7V) ÷ hFE × IMAX-CHG – (IMAX-CHG)2 ÷ (hFE)2 × RP
CCOMP = 0.01µF to 0.047µF
VOUT
QEXT
RP
DRVC
16
Q1
15
DRVE
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13
bq24450
SLUS929 – APRIL 2009 ..................................................................................................................................................................................................... www.ti.com
External Quasi-Darlington
IMAX-CHG range:
0.6A to 15A
Minimum ΔV:
1.2V
VIN
RP = (VIN(MIN) – 0.7 V) ÷ IMAX-CHG × hFE1(MIN)hFE2(MIN)
PD = (VIN(MAX) – 0.7 V) ÷ (hFE1 × hFE2) × IMAX-CHG – (IMAX-CHG)2 ैFE1 × hFE2)2 × RP
CCOMP = 0.22µF with 470Ω series resistor to GND
VOUT
Q2
Q1
DRVC
16
Q1
15
DRVE
RP
NPN Emitter-Follower
IMAX-CHG range:
25mA to 1000mA
Minimum ΔV:
2.7V
VIN
QEXT
VOUT
RP
RP = (VIN(MIN) – VOUT(MAX) – 1.2 V) ÷ IMAX-CHG × hFE(MIN)
PD = (VIN(MAX) – VOUT – 0.7 V) ÷ hFE × IMAX-CHG – (IMAX-CHG)2 ैFE)2 × RP
CCOMP = 0.01µF to 0.047µF
DRVC
16
Q1
15
DRVE
DESIGN EXAMPLE
This section covers the design of a dual-level charger for a 6V 4Ah sealed lead-acid battery. The application is a
system where the battery is used in standby mode, and the load on the battery when it powers the system is
250mA (0.06C).
The battery parameters are (see References 1 and 2)
Final discharge voltage
1.75V per cell
5.25V
VTH
Float voltage
2.30V per cell
6.9V
VFLOAT
Voltage in boost mode
2.45V per cell
7.35V
VBOOST
Charge rate
0.05C to 0.3C
Use 0.15C = 600 mA
IMAX-CHG
VBAT(MIN)
4V
Trickle charge rate
10 mA
The charger is required to operate from a supply voltage of 9V to 13V. Therefore, the minimum input to output
differential is 1.65V. To block reverse current from the battery to the input supply use a blocking diode as in
Figure 7. This leaves only 0.65V as the differential across the external transistor, forcing the use of the
Common-Emitter PNP topology.
Figure 9 is the schematic for this charger (from Figure 7, with the pass transistor topology changed), with the
remaining task being the calculation of all the component values.
14
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bq24450
www.ti.com ..................................................................................................................................................................................................... SLUS929 – APRIL 2009
RISNS
DEXT
QEXT
SLA
Battery
External
Supply
3
2
5
IN
1
ISNS
RT
16
4
ISNSP ISNSM
IFB
DRVC
PRE-CHG 11
RA
CE 12
8
9
RB
VFB 13
bq24450
RD
BSTOP
STAT1 10
STAT2
GND
COMP
DRVE
6
14
15
CCOMP
PGOOD 7
RC
RP
Figure 9.
The first step is to decide on the value of the current in the voltage divider resistor string in FLOAT mode. This
should be substantially higher than the input bias current in the CE and VFB pins and the leakage current in the
STAT1 pin, but low enough such that the voltage on the PGOOD pin does not introduce errors. A value of 50µA
is suitable.
In FLOAT mode, STAT1 is OFF, so there is no current in RD. The voltage on the VFB pin is 2.3V.
RC = 2.30V ÷ 50µA = 46kΩ. The closest 1% value is 45.9kΩ.
VFLOAT = VREF × A + RB + RC) ÷ RC → RA + RB = 2×RC = 91.8kΩ.
VBOOST = VREF × A + RB + RC//RD) ÷ RC//RD → RD = 469.2kΩ. Pick the closest 1% value of 464kΩ.
VTH = VREF × A + RB + RC//RD) ÷ B + RC//RD) → RB = 36.8559kΩ. The closest 1% value is 36.5kΩ.
RA = 91.8kΩ – RB = 46.5kΩ. The closest standard value is 46.4kΩ.
IPRE = (VIN – VBAT) ÷ RT → RT = 500Ω. Select 499Ω. At VIN(MAX), IPRE = 16mA, which is safe.
IMAX-CHG = VILIM ÷ RISNS → RISNS = 250mV ÷ 600mA = 0.417Ω. The closest 1% value is 0.422Ω.
For QEXT, the BD242 is suitable, and a 1N4001 will do for DEXT
RP = (VIN(MIN) – 2.0V) ÷ IMAX-CHG × hFE(MIN) = 7 ÷ 0.6 x 25 = 291.6Ω. Pick 294Ω from the standard values.
PD = (VIN(MAX) – 0.7V) ÷ hFE × IMAX-CHG – (IMAX-CHG)2 ÷ (hFE)2 × RD = 126mW under worst case conditions.
Choose CCOMP = 0.1µF.
REFERENCES
1. Yuasa Battery Co., NP Valve Regulated Lead Acid Battery Manual
2. Panasonic, Methods of charging the Valve-Regulated Lead-Acid Battery
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15
PACKAGE OPTION ADDENDUM
www.ti.com
20-Apr-2009
PACKAGING INFORMATION
Orderable Device
Status (1)
Package
Type
Package
Drawing
Pins Package Eco Plan (2)
Qty
BQ24450DW
ACTIVE
SOIC
DW
16
BQ24450DWTR
ACTIVE
SOIC
DW
16
40
Lead/Ball Finish
MSL Peak Temp (3)
Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
2000 Green (RoHS &
no Sb/Br)
CU NIPDAU
Level-2-260C-1 YEAR
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in
a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check
http://www.ti.com/productcontent for the latest availability information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements
for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered
at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and
package, or 2) lead-based die adhesive used between the die and leadframe. The component is otherwise considered Pb-Free (RoHS
compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame
retardants (Br or Sb do not exceed 0.1% by weight in homogeneous material)
(3)
MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder
temperature.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is
provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the
accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and continues to take
reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on
incoming materials and chemicals. TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited
information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI
to Customer on an annual basis.
Addendum-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
17-Apr-2009
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
BQ24450DWTR
Package Package Pins
Type Drawing
SOIC
DW
16
SPQ
Reel
Reel
Diameter Width
(mm) W1 (mm)
2000
330.0
16.4
Pack Materials-Page 1
A0 (mm)
B0 (mm)
K0 (mm)
P1
(mm)
W
Pin1
(mm) Quadrant
10.85
10.8
2.7
12.0
16.0
Q1
PACKAGE MATERIALS INFORMATION
www.ti.com
17-Apr-2009
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
BQ24450DWTR
SOIC
DW
16
2000
346.0
346.0
33.0
Pack Materials-Page 2
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