LiFeBATT Presentation

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LiFeBATT Presentation
New York State
LiFeBATT Corp.
© 2014
LiFeBATT Presentation 12-14-14
Topics
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LiFeBATT Management Team
LiFeBATT Background
Products
– Cells and Batteries
– Battery Management Systems
Markets
Manufacturing
Training Overview
Questions
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Management Team
• Michelle Robinson
– Chief Operations Officer
• Phillip Wright
– Chief Executive Officer
• Don Harmon
– Chief Marketing Officer
• Don Gerhardt
– Chief Technology Officer
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Management Team
Michelle Robinson – COO
• Co-founder of LiFeBATT along with Don Harmon
• BA in Business Administration and Computer
Science – Univ. of Maryland Okinawa
• Native of Taiwan
• Fluent in Chinese languages, Taiwanese and
English
• Experience as sales manager for import-export
of computer and electronics components
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Management Team
Phillip Wright – CEO
• Account Executive at Dan River Inc.
responsible for sales
• Military Marketing Manager for the
International Textile Group
• Co-founder of Solar Marine Solutions
battery operated boat lifts
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Management Team
Don Harmon – Chief Marketing Officer
• Co-founder of LiFeBATT along with
Michelle Robinson
• B.S. Industrial Design – University of
Cincinnatti
• Walt Disney Imagineering Division
• Founded the Form Factory in 1999
• Developed the Rapture electric 3 wheel
trike
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Management Team
Don Gerhardt - CTO
• BSME - Purdue University
• PhD Engineering & MBA – University of Michigan
• Engineering, Purchasing, Product Planning and Management
positions at GM, Ford and Ingersoll-Rand
• Experience with the design of cars, medium and class 8 trucks,
construction equipment and electric golf and utility vehicles
• Experience with engineering installations of Cummins, Cat, DDA,
Deutz, Isuzu, Kubota and Yanmar diesel engines
• Trustee of the Miles Value Engineering Foundation
• Director of Supplier Quality and Technology at Ingersoll-Rand
• Responsible for advanced technology including batteries at I-R Club
Car, ThermoKing and Schlage Security Systems
• Directed over 100 Value Engineering Leaders for I-R and suppliers
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LiFeBATT Background
• Private corporation
• World headquarters in Danville VA
• Specializes in advanced engineering
applications with lithium battery technology
• Used lithium battery technology developed
at the University of Texas and licensed by
Phostech Lithium Inc.
• Future batteries will use 5 volt electrolyte
developed by the US Army
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LiFeBATT Significant Events
• 2008
– Agreement signed with Phostech Lithium to
use the advanced technology developed at
the Univ. of Texas for lithium iron phosphate
cells
– LiFeBATT owns the trademark to the name
LiFeBATT
– Sandia National Laboratories publishes
positive report on LiFeBATT cells
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LiFeBATT Significant Events
• 2009
– Initial evaluation applications with cylindrical
cells
• 2010
– LiFeBATT worldwide headquarters moved to
Danville VA
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LiFeBATT Significant Events
• 2011
– LiFeBATT signs European distributor agreement with
Toyota Tsusho
– Concorde Battery informs LiFeBATT that after 3 years
of testing LiFeBATT has the best and safest battery.
Concorde plans to use LiFeBATT cells for future
aviation batteries
• 2012
– LiFeBATT begins production of new P-20 prismatic
cells
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LiFeBATT Significant Events
• 2013
– LiFeBATT achieved approval from the Mine Safety &
Health Administration (MSHA) of the Dept. of Labor
for use in underground mine applications
• 2014
– Began supplying production batteries to
American Mine Research for use in
underground Wi-Fi systems
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LiFeBATT Mission Statement
To provide the highest value
and safest battery systems to
our customers using advanced
cost effective technology.
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LiFeBATT USA Mission
Statement
• LiFeBATT will bring Lithium battery cell
manufacture to US by 2015 and provide
employment up to 500 by 2020.
• LiFeBATT will provide for energy storage and
Micro grid systems for supporting existing grid in
major cities.
• Enable US companies to assembly and develop
DC product applications.
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LiFeBATT Vision Statement
• Empowering employees and our suppliers to
provide the highest level of service and safe cost
effective battery technology to our customers.
• To provide training and employment in the local
areas where LiFeBATT facilities are located.
•To invest in efficient production facilities in the
local areas where LiFeBATT facilities are located.
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LiFeBATT Danville Building
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LiFeBATT Danville Building
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SANDIA Report on LiFeBATT Battery
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SANDIA Report on LiFeBATT Battery
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SANDIA Report on LiFeBATT Battery
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SANDIA Report on LiFeBATT Battery
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LiFeBATT Product Progression
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2008 C10 AHr Cylindrical cell
2010 C14 AHr Cylindrical cell
2012 P18 & P20 AHr Prismatic cells
Future Plans
– 5 volt electrolyte developed by US Army
– Additional cell manufacturing in the USA
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Original LiFeBATT C10 Ah Cell
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12v Battery with 10Ah Cells
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LiFeBATT 14Ah 48V LiFePO4
Battery
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LiFeBATT 36V LiFePO4 Battery
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Case Design for Prismatic Cells
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Automotive Application
Large Battery Pack with BMS
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Light Electric Vehicle
Application
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Prismatic Cell Height Comparison
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LiFeBATT P18 Ah Specification
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LiFeBATT P18 Ah Specification
(1 of 3)
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LiFeBATT P18 Ah Specification
(2 of 3)
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LiFeBATT P18 Ah Specification
(3 of 3)
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LiFeBATT P20 Ah Specification
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LiFeBATT P20 Ah Specification
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LiFeBATT P20 Ah Specification
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Battery Management System
Functions
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Protect the battery
Optimize the battery performance
Record and store information
Communication
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Battery Management System
Protection Functions
• Prevent the cells in a battery from going
below their low voltage threshold
• Prevent the cells in a battery from going
above their high voltage threshold
• Protect cells from exceeding their
temperature limit
• Protect cells from exceeding their current
limits
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LiFeBATT Battery Management
LiFeBATT has two different approaches
to battery management in order to
provide the most optimum solution for
the application
1. BMS circuit boards
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Used for small applications up to 100 amps
2. VMS circuit boards
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Used for large applications over 100 amps
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LiFeBATT Battery Management
BMS Circuit Boards
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Used for applications up to 100 amps
The BMS boards have Mosfet switches on the
board that can switch up to 100 amps
VMS Circuit Boards
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Use in conjunction with external contactor relays
that can switch from 100 amps to 1000 amps or
more
An Intermediary Module (IM) with microprocessor
control is used to control the contactor relays
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Battery Management System
BMS
Negative wire to Anderson output plug
BMS Wire
Harness
Negative wire
from cell 4
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BMS Circuit Board
Negative output
to Anderson
connector
Negative input
from cell 4
6 mm screw
12 V input
wire from
cell 1 positive
terminal
Thermocouple
Connection
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BMS wire harness connection
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VMS Circuit Board on Opposite
Side of Training Battery
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LiFeBATT Battery Management
System
There are five different BMS circuit boards
1. BMS4S - 4 cells in series for 12 volts
2. BMS5S – 5 cells in series for 15 volts
3. BMS8S – 8 cells in series for 24 volts
4. BMS12S – 12 cells in series for 36 volts
5. BMS16S – 16 cells in series for 48 volts
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LiFeBATT BMS4S Specifications
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Maximum charge current: 100 Amps
Maximum discharge current: 100 Amps
Maximum balance capability: 100 mA
4 ports of accurate A/D converters that
limit the balance tolerance within 50 mV
• Maximum pack module: 2 in series
• Records error codes and cycles used
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LiFeBATT BMS4S Specifications
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High voltage cell cutoff: 3.93 V
Low voltage cell cutoff: 2.35 V
High discharge current cutoff: 115 amps
Cell temperature warning: over 55 C
MOSFET temperature over 85 C
UART port communication
Wake up criterion: charger or discharge current
of 3 amps, charger voltage 1 volt over pack
voltage
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LiFeBATT VMS
LiFeBATT has two different VMS circuit boards.
1.
Standard speed VMS
• Can be used for up to 11 battery packs
2. High speed VMS
• Communication up to 115.2 Kbps
• Serial connection up to 120 battery packs at 19.2
Kbps
• Additional Intermediary Modules (IM) can be used
for larger systems than 120 packs
• Size is 70mm x 65 mm x 9.5mm
• Used on training batteries
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LiFeBATT VMS
• One VMS circuit board is used for every 4
cells
• Each VMS in the battery system has its
own identification number
• The computer can read the data stored in
each VMS
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LiFeBATT VMS Specifications
• Over voltage protection
– 3.8 V buzzer on and off every second
– 3.95 V OVP and LED signals change to high
– 4.2 V High voltage error recorded to MCU
• Low Voltage Protection
– 2.6 V buzzer on and off every second
– 2.0 V LVP and LED signals change to high
– 1.9 V Low voltage error recorded to MCU
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D-9 Interface Connectors from
VMS Circuit boards
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D-9 Connectors for Communication
to IM Module
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Lithium Battery with 3 VMS Boards
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LiFeBATT 14Ah 48V LiFePO
Battery with 4 VMS Boards
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Intermediary Module (IM)
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IM Connection Schematic
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IM Module connected to D-9 Display
Board Connectors on Battery
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Lithium Battery Charging Methods
• Charge each cell individually via wires
going to each cell
• Shunt current away from the high cell
group via the balance tap
• Shut off charge and bleed current off the
high cell group until it’s discharged a bit,
then resume charging
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Lithium Ion Charging
Constant Current - Constant Voltage
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24 Volt 45 Amp Lithium Battery
Charger
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36 Volt 16 Amp Lithium Battery
Charger
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Market Applications - Vehicles
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Cars
Trucks
Buses
Motorcycles and work bikes
Light electric vehicles
Aircraft
Boats
Robots
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Market Applications - Industrial
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Lawn mowers
Leaf blowers
Hedge trimmers
Floor sweepers
Pool cleaner robots
Heavy duty portable construction tools
Assembly tools
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Market Applications - Energy
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MicroGrid Systems
Solar energy storage
Back up energy
Lighting
Security
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Market Applications
Energy Box
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Market Applications
Energy Box
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Market Applications
Energy Box
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Solar Slate
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Solar Battery Powered Street
Lights
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Market Applications Recreational
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Boat lifts
Camper off grid
Electric bikes
Electric surfboards
Scuba tugs
Trolling motors
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Market Applications – Boat Lift
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Market Applications - Other
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Training
University research
Military
Drones
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LiFeBATT Taiwan Cell
Manufacturing Building
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LiFeBATT Taiwan Cell
Manufacturing Building
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LiFeBATT Taiwan Cell
Manufacturing Building
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LiFeBATT Cell Manufacturing
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Battery Training System
• LiFeBATT has developed a battery training system that
can be used at education institutions and industry
locations
• The training covers all major battery chemistries with an
emphasis on lithium batteries
• The training system is a complete package that includes:
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Lecture presentations
Laboratory exercises, quizzes and tests
Basic and Advanced training stations
Lithium batteries and all chargers, battery analyzers, software
and test equipment required to complete the course
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Inaugural Course was in May 2011
at the Danville VA Cyber Park
Danville Community College and Institute for
Advanced Learning and Research
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www.lifebatt.com
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Battery Training Stations
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Students Testing a Lithium Battery
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Battery Discharge Test with 100 Watt WMR
Tester and EXTECH DC Clamp Meter
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Volts vs AmpHrs Discharge Curve
for a LiFe 20 Amp Hr Single Cell
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Screen Showing Battery Discharge
Test from 36 Volt Lithium Battery
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Battery Discharge Test with 500
Watt WMR Amplifier
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Questions
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