KASIN KA35S281-DI

Charge Control
DATA SHEET
KA35S280;KA35S281
Lead-Acid Battery Charger
Product Specification
Kasin
Corporation
2011 Nov 18
KA35S280/281
Lead-Acid Battery Charger
Features:

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
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Optimum Control for Maximum Battery Capacity and Life
Applicable to Various Types of Lead Battery
Pin-Selectable Charge Algorithms (3 Step Voltage, Current, or Pulsed Charge)
Automatically Shorted, Opened, or Damaged Cells Detections
Automatically Battery Removal Detection
Charge Condition LED Indicator Outputs (On, Pulsed, Off)
Automatic Correction of Charging Current and Voltage Based on Current Temperature
Maximum and Minimum Battery Temperature Protection
Pre-Charge Qualification (Initial Trickle Charge for Deeply Discharged Batteries)
Cycle/Float Button (For In-System Battery Charge Condition)
Adjustable Charging Time Control by Changing the External Current Resistor
Faster Charge Time Button
Externally Disabling Charge Button
Switch Mode Constant Current Generation
Pb-Free (RoHS Compliant)
Applications:




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
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Handheld Equipment
Portable Instruments and Communications
Power Conditioning for Battery Systems
Telecommunications
Power Utility
Emergency Lighting
Control System
Fire & Security
Renewables
UPS
Description:
The KA35S28X series of battery charger controllers contain all of the necessary circuitry to
optimally control the charge and hold cycle for sealed lead-acid batteries. These integrated
circuits monitor and control both the output voltage and current of the charger through three
separate charge states; a high current bulk-charge state, a controlled over-charge, and a
precision float-charge, or standby, state.
The Pulse-Width Modulator (PWM) provides control for high-efficiency current and voltage
regulation. It allows the KA35S28X to control 3-step constant-voltage, constant current, or
pulsed-current charging. A charge cycle begins when power is applied or the battery is
replaced. For safety, charging is inhibited until the battery voltage is within configured limits.
If the battery voltage is less than the low-voltage threshold, the KA35S28X provides tricklecurrent charging until the voltage rises into the allowed range. This procedure prevents highcurrent charging of cells that are possibly damaged or reversed.
Charging is inhibited anytime if the temperature of the battery is outside the configurable,
allowed range. All voltage thresholds, in accordance with battery manufacturer's
recommendations, are change proportional to the temperature conditions.
KA35S28X can receive the types of charging algorithm or stop charging commands from its
mode selection pins. Also it can change the voltage thresholds when battery is connected to
an electronic circuit or raises charge speed by 25% only by individual pins that named as
"cycle/float" and "faster charge".
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
Ordering information:
Table 1. Ordering information
Type Number
KA35S280-DN
KA35S280-DI
KA35S280-SN
KA35S280-SI
KA35S281-DN
KA35S281-DI
KA35S281-SN
KA35S281-SI
Temperature Range
-20°C to +85°C
-40°C to +125°C
-20°C to +85°C
-40°C to +125°C
-20°C to +85°C
-40°C to +125°C
-20°C to +85°C
-40°C to +125°C
Pins
14
14
14
14
14
14
14
14
Package
Package
DIP14
DIP14
SO14
SO14
DIP14
DIP14
SO14
SO14
Material
Plastic
Plastic
Plastic
Plastic
Plastic
Plastic
Plastic
Plastic
Code
SOT27-1
SOT27-1
SOT108-1
SOT108-1
SOT27-1
SOT27-1
SOT108-1
SOT108-1
Pinning information
-
Pining
KA35S28X
1
2
3
4
5
6
7
VDD
VSS
SW
VBAT
MS0
I SNS
MS1
LED0
Faster
LED1
Cyclic/Float
LED2
TEMP
LED3
14
13
12
11
10
9
8
Figure 1 - Pin configuration
-
Pin description
Table 2 – pin Description
Symbol
VDD
SW
MS0
MS1
Faster
Cyclic /
TEMP
LED3
LED2
LED1
LED0
ISNS
VBAT
VSS
Float
Pin
1
2
3
4
5
Description
5.0V±10% power
PWM Control Output
Mode Select 0
Mode Select 1
25% Faster Charging
6
7
8
9
10
11
12
13
14
Select Between Cyclic and Float Applications
Temperature Sense Input
Charge status output 3
Charge status output 2
Charge status output 1
Charge status output 0
Current Sense Input
Battery Voltage Sense Input
System Ground
2011 Nov 18
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KA35S280/281
Lead-Acid Battery Charger
Functional diagram:
KA35S28X Block Diagram
+
TEMP
V LTF
-
V HTF
+
I Max
+
SW
Reset
MS0
1
+
But. Press
En
5mV
MS1
Phase
Controller
Unit
+-
2
3
Source Select: 0- Current
Comp.
-
A
10
+
1- Voltage
B
Cyc/Flt
4
4
A>B
5
LED0
1
Counter
7
ADC
Up
CNT
VFLT
1
0
Down
4
50mV
MUX
+-
Clk
Osc.
VMax
0
LED2
VBLK
MUX
6Hz
LED1
VMin
Ref. Gen.
Comp.
A
90
B
LED3
4
A>B
A=B
VDD
4
3
Temp.
compensation
-
0
50mV
MUX
VSS
3
V FLT
1V
Min
1
1
2
2
VMax
3
Faster Charge
VDD
2
I Th
MUX
0
VDD
I Max
-
0
1
+-
I Min
I Cond
+
+
5
I SNS
MUX
V BLK
Temp.
compensation
VBAT
Figure 2 – KA35S28X Block Diagram
Functional description:
The KA35S28X functional operation is described in terms of:
 Pin configuration
o Mode selection pins
o Faster Charge pin
o Cyclic/Float use pin
 Fixed and Configurable Thresholds
 Charge algorithms
o 3-Step voltage charge
o Current charge
o Pulsed-current charge
 Temperature monitoring
o Temperature compensation
o Disabling Temperature Sensing
 Charge monitoring
 Fault detection
o Battery insertion and removal
o Shorted, opened, or damaged cells detections
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KA35S280/281
Lead-Acid Battery Charger
- Pin Configuration
- Mode selection pins
The KA35S28X can be programmed into 3 different charge algorithm named as 3-step
voltage, current and pulsed current by mode selection pins. Table 3 shows the relations
between MS0/MS1 selection pins and IC operation.
Table 3 – Mode Selection pins
MS1
MS0
Mode
Description
0
0
1
1
0
1
0
1
0
1
2
3
Charge is disabled
3-step voltage charge
Current charge
Pulsed current Charge
- Faster charge pin
The faster charge pin can be change internal DC voltage threshold of max current by 25%
(50mV). In normal condition it is configured to 200mV by internal voltage reference
generator unit.
Table 4 – Mode Selection pins
Faster Pin
Description
0
1
Charge current increased by 25%
Normal current charge
- Cyclic/Float use pin
Due to recent design breakthroughs, the same battery may be used in either cyclic or
standby applications and it is necessary to set the charge voltage according to it. Inaccurate
voltage settings cause over- or under-charge. In applications where standby power is
required to operate when the power has been interrupted, continuous float charging is
recommended. Non-continuous cyclic charging is used primarily with portable equipment
where charging on an intermittent basis is appropriate.
The cyclic/float pin can be change internal charge reference voltage and method of
temperature compensation.
Table 5 – Mode Selection pins
Cyclic/Float Pin
0
1
Description
In cyclic use
In float use
- Fixed and Configurable Thresholds
The KA35S28X uses the following fixed thresholds:
VMAX
High-Cutoff Voltage: VBAT rising above this level is interpreted as battery
removal, cutting off charging current. VMAX = 0.6 * VCC.
VMIN
Low-Cutoff Voltage: VBAT dropping below this level is interpreted as battery
removal, cutting off charging current. VMIN = 0.2 * VCC.
VTH
Minimum Voltage: Used in pre-charge qualification. V TH = 0.34 * VCC.
ICOND
Conditioning Current: Used in the maintenance phase of the Current algorithm
and pre-charge qualification. ICOND = IMAX/5. IMAX is set by Equation 2.
Also the KA35S28X uses the following configurable thresholds:
VBLK
Upper voltage limit during fast charge, typically specified by the battery
manufacturers to be 2.3V in float and 2.45 in cyclic applications per cell @
25°C. KA35S28X uses 2.45V for VBLK when Cyclic/Float pin is set 0.
VFLT
Minimum charge voltage required to compensate for the battery’s self-discharge
rate and maintain full charge on the battery.
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
Fast charge current specified as a function of “C,” the capacity of the battery in
Ampere-hours (e.g., a charge rate of 1C for a 5Ah battery is 5A). Typical values
range from C/10 to C, although some battery vendors may approve higher
charge rates.
IMAX
The KA35S28X monitors battery pack voltage at the VBAT pin. A voltage divider between the
positive and negative terminals of the battery pack is used to present a scaled battery pack
voltage to the VBAT pin. The KA35S28X also uses the voltage across a sense resistor (RSNS)
between the negative terminal of the battery pack and ground to monitor current. See
Figure 3 and below equations for the configuration of this network.
Equation 1:
And IMAX is determined by:
Equation 2:
Where:
N = Number of series cells in the battery pack
IMAX = Desired maximum charge current
BAT+
V BAT
RB 1
RB 2
I BAT
BAT-
R SNS
KA35S28X
Figure 3 - Configuring the Battery Divider
The KA35S28X internal band-gap reference voltage at 25°C is 2.2V. This reference shifts
with temperature at -3.9mV/°C to compensate for the negative temperature coefficient of
lead-acid chemistry.
The total resistance presented by the divider between BAT+ and BAT- (RB1 + RB2) should
be between 100KΩ and 1MΩ. The minimum value ensures that the divider network does
not drain the battery excessively when the power source is disconnected. Exceeding the
maximum value increases the noise susceptibility of the VBAT pin. 1% resistors are
recommended.
Table 6 shows the several examples of resistor selections.
Table 6 – RB1, RB2 Values by Number of Cells and RSNS by Desired IMAX
N
RB1 (KΩ)
RB2 (KΩ)
IMAX
RSNS (Ω)
3 (6V)
6 (12V)
12 (24V)
57KΩ
147KΩ
327KΩ
33KΩ
33KΩ
33KΩ
0.5
1A
1.5A
0.4Ω
0.2Ω
0.13Ω
2011 Nov 18
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KA35S280/281
Lead-Acid Battery Charger
- Charge algorithms
- 3-Step voltage charge
VBLK
Voltage
VFLT
Fast Charge
Maintenance
VTH
Phase 2
Phase 3
I COND
Phase 4
Voltage
Current
I MAX
Qualification
This algorithm consists of four phases (figure 4):
1. Phase1 - Qualification: The charging current is limited at ICOND (=IMAX/5) until the cell
voltage rises to V TH to prevent battery damage. In this condition The KA35S28X enters
the Charge Pending state and waits until the battery voltage rises to V TH. Charge
Pending is annunciated by LED0 and LED3 flashing.
2. Phase2 - Fast Charge 1: The charging current is limited at IMAX (1.25 IMAX when faster
pin is 0) until the cell voltage rises to VBLK.
3. Phase3 - Fast Charge 2: The charging voltage is regulated at VBLK until the charging
current drops below IMIN ( 0.1IMAX)
4. Phase4 - Maintenance: The charging voltage is regulated at VFLT.
Current
Phase 1
I MIN
I FLT
Time
Figure 4 – 3-Step Voltage Charge
- Current charge
VBLK
Current
VFLT
Voltage
Phase 2
VTH
Maintenance
Fast Charge
I COND
Phase 3
Phase 1
Voltage
Current
I MAX
Qualification
This algorithm consists of three phases (figure 5):
1. Phase1 - Qualification: The charging current is limited at ICOND (=IMAX/5) until the cell
voltage rises to V TH to prevent battery damage. In this condition The KA35S28X enters
the Charge Pending state and waits until the battery voltage rises to V TH. Charge
Pending is annunciated by LED0 and LED3 flashing.
2. Phase 2 - Fast Charge: The charging current is regulated at IMAX (1.25 IMAX when faster
pin is 0) until the cell voltage rises to VBLK or the “Second Difference” of cell voltage
drops below -8mV while VBAT is over 2.0V.
3. Phase3 - Maintenance: Fixed-width pulses of charging current = ICOND are modulated in
frequency to achieve an average value of IMIN (0.1IMAX).
I MIN
I FLT
Time
Figure 5 – Current Charge
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
- Pulsed-current charge
This algorithm consists of three phases (figure 6):
1. Phase1 - Qualification: The charging current is limited at ICOND (=IMAX/5) until the cell
voltage rises to V TH to prevent battery damage. In this condition The KA35S28X enters
the Charge Pending state and waits until the battery voltage rises to V TH. Charge
Pending is annunciated by LED0 and LED3 flashing.
2. Phase2 - Fast Charge: The charging current is regulated at IMAX (1.25 IMAX when faster
pin is 0) until the cell voltage rises to VBLK.
3. Phase3 - Maintenance: Charging current is removed until the battery voltage falls to
VFLT; charging current is then restored and regulated at IMAX (1.25 IMAX when faster pin is
0) until the battery voltage once again rises to VBLK. This cycle is repeated indefinitely.
Maintenance
VBLK
Current
VFLT
Voltage
Phase 2
Fast Charge
I COND
Phase 1
VTH
Voltage
Current
I MAX
Qualification
Phase 3
I MIN
I FLT
Time
Figure 6 – Fast Charge
- Temperature monitoring
- Temperature compensation
The KA35S28X senses temperature by monitoring the voltage of TEMP pin. The KA35S28X
assumes a Negative Temperature Coefficient (NTC) thermistor, so the voltage on the TEMP
pin is inversely proportional to the temperature (see Figure 7). The temperature thresholds
used by the KA35S28X and their corresponding TEMP pin voltage are:
TCO Temperature Cut-Off: Higher limit of the temperature range in which charging is
allowed. VTCO = 0.12 * VCC.
HTF High-Temperature Fault: Threshold to which temperature must drop after
Temperature Cut-Off is exceeded before charging can begin again. VHTF = 0.15 *
VCC
LTF Low-Temperature Fault: Lower limit of the temperature range in which charging is
allowed. VLTF = 0.35 * VCC.
A resistor-divider network must be implemented that presents the defined voltage levels to
the TEMP pin at the desired temperatures (see Figure 8). The equations for determining
RT1 and RT2 are:
Equation 1:
Equation 2:
Where:
RLTF = Thermistor resistance at LTF
RHTF = Thermistor resistance at HTF
1% resistors are recommended. As an example, the resistor values for several temperature
windows computed for a 3KΩ thermistor are shown in Table 7.
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
Table 7 – RT1 and RT2 Values for Temperature Thresholds
LTF (°C)
HTF (°C)
RT1
RT2
5 °C
0 °C
-5 °C
45 °C
50 °C
55 °C
8.18KΩ
7.50KΩ
6.85KΩ
15.22KΩ
11.25KΩ
8.72KΩ
.
Colder
VLTF = 0.35VCC
LTF
VHTF = 0.15VCC
HTF
VTCO = 0.12VCC
TCO
VSS
Temperature
Voltage
VCC
Hotter
Figure 7 – Voltage Equivalent of Temperature Threshold
VCC
RT1
TEMP
NTC
Thermistor
RT2
KA35S28X
Figure 8 – Configuring Temperature Sensing
- Disabling Temperature Sensing
Temperature sensing may be disabled by removing the thermistor and use a single Pull up
or Pull down resistor connected to TEMP pin as shown in figure 9.
VCC
TEMP
Or
RPU
TEMP
RPD
KA35S28X
KA35S28X
Figure 9 – Disabling Temperature Sensing
where:
RPU = Pull up resistor (Can be select 1KΩ)
RPD = Pull down resistor (Can be select 1KΩ)
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
- Charge monitoring
Charge status (figure 10) is annunciated by the LED driver outputs LED1 - LED3 (figure 11)
2.6 Voltage Profile for
Lead-Acid Charging with
Constant Current Regulation
2.5
Voltage per Cell, V
2.4
2.3
2.2
2.1
Charge Rate = C/20
2.0
1.9
0
25
50
75
100
125
150
Previous Discharge Capacity Returned, %
Figure 10 - Voltage Roll-Off In Constant Current Charging Profile
R
LED0
LED0
R
LED1
LED1
R
LED2
LED2
R
LED3
LED3
KA35S28X
Figure 11 – LED Display
- Fault detection
- Battery insertion and removal
The KA35S28X uses VBAT to detect the presence or absence of a battery. The KA35S28X
determines that a battery is present when VBAT is between the High-Voltage Cutoff and the
Low-Voltage Cutoff. When VBAT is outside this range, the KA35S28X determines that no
battery is present and transitions to the Fault state. Also, sudden changes in battery voltage
can cause the fault state.
- Shorted, opened, or damaged cells detections
The KA35S28X can be detect shorted, opened, and damaged cells by using one of the
following below state:
1. High current detection
2. Non-rechargeable batteries detection
3. Changing in any of the buttons
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
Typical Application
Switch
Network
3300uF (50V)
1N4007 (1A)
7805
+
BAT+
1
15 (7) - 30 V
2
3
4
5
6
7
VDD
VSS
SW
VBAT
MS0
I BAT
MS1
LED0
Faster
LED1
Cyclic/Float
LED2
TEMP
LED3
14
RB 1
13
12 (6) V
12
RB
2
11
BAT-
10
9
1N4007 (1A)
8
R
SNS
KA35S28X
N
RB1 (KΩ)
RB2 (KΩ)
IMAX
RSNS (Ω)
3 (6V)
6 (12V)
12 (24V)
57KΩ
147KΩ
327KΩ
33KΩ
33KΩ
33KΩ
100mA
300mA
500mA
2Ω
0.66Ω
0.4Ω
Figure 12 – A Very Simple High Power 3-Step Voltage Lead-Acid Battery Charger
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
Typical Application
33KΩ
IRF9530
3300uF (50V)
1N4007 (1A)
7805
+
BAT+
15 (7) - 30 V
22KΩ
1
1KΩ
2
3
4
5
6
7
VDD
VSS
SW
VBAT
MS0
I BAT
MS1
LED0
Faster
LED1
Cyclic/Float
LED2
TEMP
LED3
14
RB 1
13
12 (6) V
12
RB
2
11
BAT-
10
9
1N4007 (1A)
R
8
SNS
KA35S28X
N
RB1 (KΩ)
RB2 (KΩ)
IMAX
RSNS (Ω)
3 (6V)
6 (12V)
12 (24V)
57KΩ
147KΩ
327KΩ
33KΩ
33KΩ
33KΩ
100mA
300mA
500mA
2Ω
0.66Ω
0.4Ω
Figure 13 – Schematic Diagram of A Very Simple High Power 3-Step Voltage Lead-Acid
Battery Charger
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
Typical Application
39
mm
57 mm
Figure 14 – Schematic Diagram and PCB Layout of a Very Simple 3-Step Voltage of LeadAcid Battery Charger
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
Typical Application
51
mm
80 mm
Figure 15 – Schematic Diagram and PCB Layout of Lead-Acid Battery Charger with
Programmable Charge Algorithm, Faster and Cyclic Charge Buttons, LED Display,
Selectable DC or AC Power Input and Temperature Sensor
2011 Nov 18
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Lead-Acid Battery Charger
Absolute Maximum Ratings:
Table 8 – Absolute Maximum Ratings
Symbol
Parameter
VDD
VCC relative to VSS
DC voltage applied on any pin
VT
excluding VDD relative to VSS
TOPR
Operating ambient temperature
TSTG
Storage temperature
TSOLDER Soldering temperature
*- In KA35S28X-XI series.
Min.
Max.
Unit
-0.3
6.5
V
-0.3
6.5
*
-20 (-40 )
-55
---
Note
V
*
+85 (+125 )
+125 (+150*)
+260
°C
°C
°C
10 s. max.
DC Thresholds:
Table 9 – Absolute Maximum Ratings
Symbol
Parameter
VLTF
VHTF
VTCO
VMAX
VMIN
VTH
Internal reference voltage
Temperature coefficient
TEMP maximum threshold
TEMP hysteresis threshold
TEMP minimum threshold
High cutoff voltage
Under-voltage threshold at BAT
Low cutoff voltage
VSNS
Current sense at SNS
VREF
Rating
Unit
Tolerance
Note
2.00
-3.9
0.35*VDD
0.15*VDD
0.12*VDD
0.6*VDD
0.2*VDD
0.34*VDD
0.200
0.040
V
mV/°C
V
V
V
V
V
V
V
V
1%
10%
±0.02V
±0.02V
±0.02V
±0.02V
±0.02V
±0.02V
10%
10%
TA=25°C
IMAX
ICond
Recommended operating conditions:
Table 10 – Absolute Maximum Ratings
Symbol
Parameter
VDD
Supply voltage
TEMP voltage
potential
Battery voltage
potential
Supply current
Logic input high
Logic input low
LEDX output high
LEDX output low
LEDX output source
LEDX output sink
logic input low source
logic input high
source
VTEMP
VBAT
ICC
VIH
VIL
VOH
VOL
IOH
IOL
IIL
IIH
Min.
KA35S28X-XN
Typ.
Max.
Min.
KA35S28X-XI
Typ.
Max.
Unit
4.5
5.0
5.5
4.5
5.0
5.5
V
0
-
VDD
0
-
VDD
V
0
-
VDD
0
-
VDD
V
VDD-0.6
VDD-0.7
-15
15
-
3
-
5
VSS+0.3
VSS+0.5
35
VDD-0.6
VDD-0.7
-15
15
-
3
-
5
VSS+0.3
VSS+0.5
35
V
V
V
V
V
mA
mA
µA
-
-
-40
-
-
-40
µA
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
Package outline:
DIP16: plastic dual in-line package; 16 leads (300 mil)
SOT27-1
Seating plane
D
ME
A2
A
A1
L
c
w
e
Z
M
b1
(e 1 )
b
14
MH
8
Pin 1 index
E
1
7
0
10 mm
5
Scale
DIMENSIONS (inch dimensions are derived from the original mm dimensions)
Unit
A
max.
A1
min
A2
max.
mm
4.2
0.51
3.2
inches
0.17
0.02
0.13
b
b1
c
D(1)
E(1)
1.73
1.13
0.068
0.044
0.53
0.38
0.21
0.015
0.36
0.23
0.014
0.009
19.50
18.55
0.77
0.73
6.48
6.20
0.26
0.24
e
e1
2.54
7.62
0.1
0.3
L
ME
MH
3.60
3.05
0.14
0.12
8.25
7.80
0.32
0.31
10.0
8.3
0.39
0.33
w
Z(1)
max.
0.254
2.2
0.01
0.087
Note
1. Plastic or metal protrusions of 0.25 mm (0.01 inch) maximum per side are not included.
Figure 16 - Package outline SOT27-1
2011 Nov 18
© 2011 Kasin Technology Inc.
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KA35S280/281
Lead-Acid Battery Charger
SO14: plastic small outline package; 14 leads; body width 3.9 mm
SOT108-1
D
A
E
X
c
y
HE
v
M
A
Z
8
14
Q
A2
A
(A3 )
A1
Pin 1 index
θ
Lp
L
7
1
e
w
bp
0
Detail X
M
5 mm
2.5
scale
DIMENSIONS (inch dimensions are derived from the original mm dimensions)
Unit
A
max.
mm
1.75
inches
0.069
A1
A2
0.25
0.10
0.010
0.004
1.45
1.25
0.057
0.049
A3
0.25
0.01
bp
c
D(1)
E(1)
0.49
0.36
0.019
0.014
0.25
0.19
0.010
0.007
8.75
8.55
0.35
0.34
4.0
3.8
0.16
0.15
e
1.27
0.05
HE
6.2
5.8
0.244
0.228
L
1.05
0.041
Lp
Q
1.0
0.4
0.039
0.016
0.7
0.6
0.028
0.024
v
w
y
0.25
0.25
0.1
0.01
0.01
0.004
Z(1)
max.
0.7
0.3
0.028
0.012
Note
1. Plastic or metal protrusions of 0.15 mm (0.006 inch) maximum per side are not included.
Figure 17 - Package outline SOT108-1
2011 Nov 18
© 2011 Kasin Technology Inc.
17
θ
8°
0°
KA35S280/281
Lead-Acid Battery Charger
DATA SHEET STATUS
LEVEL
DATA SHEET
STATUS(1)
PRODUCT
STATUS(2)(3)
І
Objective data
Development
ІІ
Preliminary
data
Qualification
ІІІ
Product data
Production
DEFINITION
This data sheet contains data from the objective
specification for product development. Kasin
Corporation reserves the right to change the
specification in any manner without notice.
This data sheet contains data from the preliminary
specification Supplementary data will be published at
a later date. Kasin Corporation reserves the right to
change the specification without notice, in order to
improve the design and supply the best possible
product.
This data sheet contains data from the product
specification. Kasin Corporation reserves the right to
make changes at any time in order to improve the
design, manufacturing and supply. Relevant changes
will be communicated via a Customer
Product/Process Change Notification (CPCN).
Notes
1. Please consult the most recently issued data sheet before initiating or completing a design.
2. The product status of the device(s) described in this data sheet may have changed since
this data sheet was published. The latest information is available on the Internet at URL
http://www.kasincorp.com.
3. For data sheets describing multiple type numbers, the highest-level product status
determines the data sheet status.
DEFINITIONS
Short-form specification - The data in a short-form specification is extracted from a full datasheet with the same type number and title. For detailed information see the relevant data sheet or
data handbook.
Limiting values definition - Limiting values given are in accordance with the Absolute Maximum
Rating System (IEC 60134). Stress above one or more of the limiting values may cause
permanent damage to the device. These are stress ratings only and operation of the device at
these or at any other conditions above those given in the Characteristics sections of the
specification is not implied. Exposure to limiting values for extended periods may affect device
reliability.
Application information - Applications that are described herein for any of these products are for
illustrative purposes only. Kasin Corporation make no representation or warranty that such
applications will be suitable for the specified use without further testing or modification.
DISCLAIMERS
Life support applications - These products are not designed for use in life support appliances,
devices, or systems where malfunction of these products can reasonably be expected to result in
personal injury. Kasin Corporation customers using or selling these products for use in such
applications do so at their own risk and agree to fully indemnify Kasin Corporation for any
damages resulting from such application.
Right to make changes - Kasin Corporation reserves the right to make changes in the products
including circuits, standard cells, and/or software described or contained herein in order to improve
design and/or performance. When the product is in full production (status ‘Production’), relevant
changes will be communicated via a Customer Product/Process Change Notification (CPCN).
Kasin Corporation assumes no responsibility or liability for the use of any of these products,
conveys no licence or title under any patent, copyright, or mask work right to these products, and
makes no representations or warranties that these products are free from patent, copyright, or
mask work right infringement, unless otherwise specified.
2011 Nov 18
© 2011 Kasin Technology Inc.
18
KA35S280/281
Lead-Acid Battery Charger
Notes:
Contact information:
For additional information please visit: http://www.kasincorp.com.
For sales offices addresses send e-mail to: [email protected].
© Kasin Corporation Electronics N.V. 2011
All rights are reserved. Reproduction in whole or in part is prohibited without the prior written consent of the copyright owner.
The information presented in this document does not form part of any quotation or contract, is believed to be accurate and reliable and may be
changed without notice. No liability will be accepted by the publisher for any consequence of its use. Publication thereof does not convey nor
imply any license under patent- or other industrial or intellectual property rights.
2011 Nov 18
© 2011 Kasin Technology Inc.
19