ALD ALD810022SCLI 4-channel supercapacitor auto balancing pcb Datasheet

ADVANCED
LINEAR
DEVICES, INC.
SABMB16 / SABMB810025
SABMB910025 / SABMB8100XX / SABMB9100XX
e
TM
EPAD
EN
®
AB
LE
D
4-CHANNEL SUPERCAPACITOR AUTO BALANCING PCB
GENERAL DESCRIPTION
The SABMB16 is a 4-channel universal Printed Circuit Board
(PCB) designed to be used with the entire ALD8100XX and
ALD9100XX family of SAB™ MOSFETs for system designers and
application developers. SAB MOSFETs are exclusive EPAD
MOSFETs that address leakage and voltage balance of
supercapacitor cells connected in series. Imbalance of leakage
currents, although much smaller in magnitude than charging or
discharging currents, need to be balanced, as leakage currents
are long-term DC values that integrate and accumulate over time.
SAB MOSFETs and the SABMB16 boards are compact,
economical and effective in balancing any size supercapacitors
with little or no additional power dissipation. Each SABMB16 can
balance two to four supercapacitors in a series stack. These boards
can be cascaded to balance multiple series stacks of up to four
supercapacitors each.
SABMB910025 is a SABMB16 board with two ALD910025SALI
installed and tested. These are rated for industrial tempurature of
-40°C to +85°C.
®
The SABMB16 board includes the following features for flexibility
in a variety of different applications:
2)
3)
4)
The SABMB16 is a simple, out-of-the-box plug-and-play PCB
solution for development, prototyping, demonstration and
evaluation, or production deployment. It is suited for balancing
supercapacitor stacks ranging from two in series to hundreds in
series, and for supercapacitors of 0.1F to 3000F and beyond. The
average additional power dissipation due to use of SABMB boards
is zero, which makes this method of supercapacitor balancing
very energy efficient. It is especially suited for low loss energy
harvesting and long life battery operated applications.
5)
6)
7)
Two ALD9100XX dual or one ALD8100XX quad SAB
MOSFET units installed per board.
Two ALD9100XX and one ALD8100XX can be installed
on the same SABMB16 board. The two ALD9100XX are
connected in series, whereas the ALD8100XX is
connected in parallel to the two ALD9100XX units.
Optional R1 and R2 resistors can be installed with values
ranging from open circuit to 0.0Ω.
Optional reverse biased external clamping power diodes
(schottky rectifiers) can be installed, on board where
necessary, across each SAB MOSFET.
Multiple SABMB16 PCBs can be cascaded to form a
series chain, paralleling a series-connected chain of
supercapacitor cells.
Compact size of 0.6 in. by 1.6 in. with mounting holes.
Rated for RoHS compatible/industrial temperature range
of -40°C to +85°C.
Supercapacitors, also known as ultracapacitors, when connected
two, three or four cells in series can be balanced with ALD8100XX/
ALD9100XX packages installed on the SABMB16 board.
Supercapacitors, when connected more than four cells in series,
can be balanced with more than one SABMB16 board (each with
ALD8100XX/ALD9100XX packages installed).
MECHANICAL DRAWING
V+
SABMB16 is a blank PCB, ready for either ALD8100XX or
ALD9100XX to be installed. For example, SABMB810025 is a
SABMB16 board with one ALD810025SCLI installed and tested.
R1
U2
SABMB16
1)
A
A
B
B
ORDERING INFORMATION
1600 mil
C
Part Number
Decription
C
SABMB16
Blank Universal PCB
D
SABMB810025
SABMB16 Board with one ALD810025SCLI
SABMB910025
SABMB16 Board with two ALD910025SALI
E
SABMB8100XX
SABMB16 Board with one ALD8100XXSCLI
E
SABMB9100XX
SABMB16 Board with two ALD9100XXSALI
R2
D
U3 V-
Note: SABMB8100XX/SABMB9100XX are optional with
specific ALD8100XXSCLI or ALD9100XXSALI unit(s) installed.
XX = 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28.
600 mil
See page 4 for full listing of part numbers.
* Magnified, not to scale
©2018 Advanced Linear Devices, Inc., Vers. 1.1
www.aldinc.com
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SUPERCAPACITOR AUTO BALANCING PCB
The ALD8100XX/ALD9100XX SAB MOSFET family offers the user
a selection of different threshold voltages for various
supercapacitor nominal voltage values and desired leakage
balancing characteristics. Each SAB MOSFET generally requires
connecting its V+ pin to the most positive voltage and its V- and
IC pins to the most negative voltage within the package. Note
that each Drain pin has an internal reverse biased diode to its
Source pin, and each Gate pin has an internal reverse biased
diode to V-. All other pins must have voltages within V+ and Vvoltage limits within the same package unit.
Standard ESD protection facilities and handling procedures for
static sensitive devices must also be used while installing the
ALD8100XX/ALD9100XX units. Once installed, the connection
configuration will protect the ALD8100XX/ALD9100XX units from
ESD damage. When connected to a supercapacitor stack, the
ALD8100XX/ALD9100XX is further protected from virtually any
ESD damage due to the large capacitance of the supercapacitors,
which sinks any ESD charge and thereby reduces any of the
terminal voltages to minimal harmless values.
Any number of SABMB16 boards can be daisy-chain connected
in series. For example, three SABMB16 boards, each with an
ALD810025SCLI installed, can be connected in series to a 30V
power supply, provided care is taken to insure that each SABMB16
board V- is connected to the V+ of the next SABMB16 board in
series, such that each board would not have internal voltages from
V+ to V- exceeding 10V (30V/3 = 10V).
The ALD8100XX/ALD9100XX is rated for reverse bias diode
currents of up to 80mA maximum for each SAB MOSFET on board.
Any reverse bias condition as a result of changing supercapacitor
voltages, especially during fast supercapacitor discharge, could
lead to some internal nodes temporally reverse biased with surge
current in excess of this limit. The SABMB16 board has additional
optional TO277 footprints for mounting external schottky rectifiers
(power diodes) to clamp such current transients. The user is
advised to determine the various power and current limits, including
temperature and heat dissipation considerations, when selecting
a suitable component for such purpose. The appropriate level of
derating and margin allowance must also be added to assure long
term reliability of the PCB board.
SABMB16 PRINTED CIRCUIT BOARDS
SUPERCAPACITORS
The SABMB16 Printed Circuit Board is supplied as a blank PCB
board, made with RoHS compliant FR4 material, ready for
mounting of up to two 8-lead ALD9100XX units or one 16-lead
ALD8100XX unit. These units are also supplied and available with
a 6-digit suffix, which denotes the specific ALD9100XX or
ALD8100XX component mounted and tested on the PCB. All that
is required of the user is to mount the PCB and wire the appropriate
connections from the SABMB16 board to the respective
supercapacitor nodes.
Each SABMB16 Printed Circuit Board has two 8-lead SOIC
footprints, for up to two ALD9100XX units, and a 16-lead SOIC
footprint, for one ALD8100XX, which is parallel connected to the
two ALD9100XX footprints (See schematic diagram). It has
terminals labeled V+, A to E, and V-. Each of these terminals has
two wiring holes for easier connection of the same terminal node
to two external connection points. V+ is directly connected to
terminal A, which must be connected to the most positive voltage
for the individual SABMB16 PCB board. V- is directly connected
to terminal E, which must be connected to the most negative
voltage present for the same SABMB16 board. All other terminals,
namely B, C and D, must have voltages between V+ and V- for
proper operation of the board. When cascade or daisy-chain
connected, each SABMB16 board is self-contained and rated for
15.0V maximum.
When two supercapacitors are installed to be balanced by SAB
MOSFETs, a single ALD9100XX unit can be mounted on either
one of two 8-lead SOIC footprints on the SABMB16. The user
then needs to connect the unused circuit traces to the appropriate
terminals so that V+ and V- remain the most positive voltage and
the most negative voltage for that SABMB16 board, respectively.
For example, if only one ALD9100XX is used for the upper SOIC
footprint, terminal C can be connected to terminal E, or V-. One
convenient way to make this connection on board is to install R2
with a value equal to 0 Ω or use an external wire.
SABMB16/SABMB810025/SABMB910025
SABMB8100XX/SABMB9100XX
Supercapacitors are typically rated with a nominal recommended
working voltage established for long life at their maximum rated
operating temperature. Excessive supercapacitor voltages that
exceed the supercapacitor’s rated voltage for a prolonged time
period will result in reduced operating life and eventual rupture
and catastrophic failure. To prevent such an occurrence, a means
of automatically adjusting (charge-balancing) and monitoring the
maximum voltage is required in most applications having two or
more supercapacitors connected in series, due to the different
internal leakage currents that vary from one supercapacitor to
another.
Each supercapacitor has a tolerance difference in capacitance,
internal resistance and leakage current. These differences create
imbalance in cell voltages, which must be balanced so that any
individual cell voltage does not exceed its rated max. voltage.
Initially, cell voltage imbalance is caused by capacitance value
differences. Supercapacitors selected from the same manufacturer
make and model batch can be measured and matched to deliver
reasonable initial cell voltages. Next, cell voltage imbalance due
to individual cell leakage currents must be compensated.
The supercapacitor leakage current itself is a variable function of
its many parameters such as aging, initial leakage current at zero
input voltage, the material/construction of the supercapacitor, and
the operating bias voltage. Its leakage is also a function of the
charging voltage, the charging current, operating temperature
range and the rate of change of many of these parameters.
Supercapacitor balancing must accommodate these changing
conditions.
By using the appropriate ALD SAB MOSFET and the appropriate
SABMBXX board, users can compensate for all of these causes
of imbalance and automatically balance supercapacitors.
Advanced Linear Devices, Inc.
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SUPERCAPACITOR AUTO BALANCING PCB
ENERGY HARVESTING APPLICATIONS
CONNECTION TO OTHER SABMBxx PCBs
Supercapacitors offer an important benefit for energy harvesting
applications from a low energy source, by buffering and storing
such energy to drive a higher power load.
The SABMB16 is compatible with other SABMBXX boards and is
designed to be used along with other SABMBXX boards connected
in series to achieve balancing the corresponding number of
supercapacitors installed in a series stack. For example, five
supercapacitors in series can be balanced with one SABMB16
PCB and one SABMB2 PCB connected in series.
SAB MOSFETs used for charge balancing, due to their high input
threshold voltages, would be completely turned off initially,
consuming zero drain current while the supercapacitor is being
charged, maximizing any energy harvesting gathering efforts. The
SAB MOSFET does not become active until the supercapacitor is
already charged to over 90% of its max. rated voltage. The trickle
charging of supercapacitors with energy harvesting techniques
tends to work well with SAB MOSFETs as charge balancing
devices, as it is less likely to have high transient energy spurts
resulting in excessive voltage or current excursions.
For more information on the CHARACTERISTICS OF
SUPERCAPACITOR AUTO BALANCING (SABTM) MOSFETS,
please refer to the following documents:
* ALD8100XX/ALD9100XX FAMILY of SUPERCAPACITOR
AUTO BALANCING (SABTM) MOSFET ARRAYS
* Individual datasheet for chosen SAB MOSFET.
CAUTION:
Users must limit the voltage across any ALD9100XX chip to
15.0V max.
SABMB16 PCB CONNECTION TO
SUPERCAPACITORS C1, C2, C3, C4
V+
V+
R1
If an energy harvesting source only provides a few µA of current,
the power budget does not allow wasting any of this current on
capacitor leakage currents and power dissipation of resistor or
operational amplifier based charge-balancing circuits. It may also
be important to reduce long term leakage currents, as energy
harvesting charging at low levels may take up to many days.
SABMB16
For energy harvesting applications, supercapacitor leakage
currents are a critical factor, as the average energy harvesting
input charge must exceed the average supercapacitor internal
leakage currents in order for any net energy to be harvested and
saved. Often, the input energy is variable, meaning that its input
voltage and current magnitude are not constant and may be
dependent upon a whole set of other parameters such as the
source energy availability, energy sensor conversion efficiency,
changing environmental conditions, etc.
U2
A
VA
A
C1
B
B
VB
C2
C
C
R2
D
VC
C3
D
VD
C4
E
VE
E
U3 V-
V- TO NEXT BOARD V+
V+ TO NEXT BOARD VV+
R1
SABMB16
In summary, in order for an energy harvesting application to be
successful, the input energy harvested must exceed all the energy
required, due to the leakages of the supercapacitors and the
charge-balancing circuits, plus any load requirements. With their
unique balancing characteristics and near-zero charge loss, SAB
MOSFETs are ideal devices for use in supercapacitor chargebalancing in energy harvesting applications.
U2
A
VA
A
C1
B
B
BATTERY POWERED APPLICATIONS
VB
C2
C
C
R2
D
C3
VD
C4
E
VE
E
U3 V-
V- TO NEXT BOARD V+
V+ TO NEXT BOARD VV+
R1
U2
SABMB16
Many battery powered circuits requiring a supercapacitor to boost
power output can benefit from using SAB MOSFETs for
supercapacitor balancing. The additional power burn by using SAB
MOSFETs for supercapacitor stack balancing can actually be
negative, as adding SAB MOSFETs can save supercapacitor
leakage current and associated power dissipation by lowering the
operating bias voltage of the leakier supercapacior. Applications
that depend on long life battery usage must take into account the
supercapacitor leakage current and balancing circuit power burn
because the currents involved are steady state DC currents that
are continuous throughout the lifetime of the application and its
battery life. The average power dissipation with the addition of the
SABMB16 board is zero, provided the selection of the operating
voltages and SAB MOSFETs are appropriate for the leakage
currents of the supercapacitors specified.
VC
D
A
VA
A
C1
B
VB
B
C2
C
C
* Magnified, not to scale
SABMB16/SABMB810025/SABMB910025
SABMB8100XX/SABMB9100XX
Advanced Linear Devices, Inc.
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SUPERCAPACITOR AUTO BALANCING PCB
SABMB16 SCHEMATIC DIAGRAM
ALD 8100xx
R1
U1
3, 8
U2
ALD9100XX
STACK 1
3
4
+
M1
D1
C1
4
6
VB
15
M2
7
VA
2,12
M1
2
V+ < +15.0V
IDS(ON) < 80 mA
14
+
M2
C2
D2
13
1, 5
VC
11
3, 8
M1
2
U3
ALD9100XX
STACK 2
10
6
M2
VD
6
7
C3
D3
9
4
7
+
M3
+
M4
D4
1, 5
C4
VE
1,5,8,16
VR2
NOTES
1. R1, R2: USER SPECIFIED VALUES
FROM OPEN CIRCUIT TO ZERO
(0.0) OHMS
2. U1: 16L SOIC ALD8100XXSCLI
U2, U3: 8L SOIC ALD9100XXSALI
3. D1, D2, D3, D4: OPTIONAL SCHOTTKY
RECTIFIER FOR REVERSE CURRENT
CLAMPING (TO277 FOOTPRINT)
4. C1, C2, C3, C4: SUPERCAPACITORS
EXTERNAL TO THE SABMB16 PCB
PCB PRODUCT PART NUMBERS
SABMB16
(blank PC Board)
SABMB810016 (SAMB16 with one ALD810016SCLI)
SABMB810017 (SAMB16 with one ALD810017SCLI)
SABMB810018 (SAMB16 with one ALD810018SCLI)
SABMB810019 (SAMB16 with one ALD810019SCLI)
SABMB810020 (SAMB16 with one ALD810020SCLI)
SABMB810021 (SAMB16 with one ALD810021SCLI)
SABMB810022 (SAMB16 with one ALD810022SCLI)
SABMB810023 (SAMB16 with one ALD810023SCLI)
SABMB810024 (SAMB16 with one ALD810024SCLI)
SABMB810025 (SAMB16 with one ALD810025SCLI)
SABMB810026 (SAMB16 with one ALD810026SCLI)
SABMB810027 (SAMB16 with one ALD810027SCLI)
SABMB810028 (SAMB16 with one ALD810028SCLI)
SABMB16/SABMB810025/SABMB910025
SABMB8100XX/SABMB9100XX
SABMB910016 (SAMB16 with two ALD910016SALI)
SABMB910017 (SAMB16 with two ALD910017SALI)
SABMB910018 (SAMB16 with two ALD910018SALI)
SABMB910019 (SAMB16 with two ALD910019SALI)
SABMB910020 (SAMB16 with two ALD910020SALI)
SABMB910021 (SAMB16 with two ALD910021SALI)
SABMB910022 (SAMB16 with two ALD910022SALI)
SABMB910023 (SAMB16 with two ALD910023SALI)
SABMB910024 (SAMB16 with two ALD910024SALI)
SABMB910025 (SAMB16 with two ALD910025SALI)
SABMB910026 (SAMB16 with two ALD910026SALI)
SABMB910027 (SAMB16 with two ALD910027SALI)
SABMB910028 (SAMB16 with two ALD910028SALI)
Advanced Linear Devices, Inc.
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