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Transcript
For Electric Vehicle Team Members •Pramit Tamrakar- Electrical Engineering •Jimmy Skadal- Electrical Engineering •Hao Wang- Electrical Engineering •Matthew Schulte- Electrical Engineering Adviser •Ayman Fayed Client •Adan Cervantes- Element One Systems Team-id- SdMay11-04 Problem Statement Develop an efficient and safe system for charging and monitoring of multi-cell series batteries in Electric Vehicles using AC to DC Switching Power Converters. System Specifications Functional Requirement Li-Ion Battery Management (90 cells in series) Constant-Current Constant-Voltage (CCCV) charging procedure Battery Gauging Temperature Monitoring Overcharge Protection Achieve 100 miles range per charge Non-Functional Requirements Generating a 324 VDC power bus from a 120V VAC outlet Ensuring safety Constraints and Technology considerations Constraints: The charging process Technology: Three Stages Charging Technology Pre - charge Constant Current stage Constant Current charging stage Constant voltage charging stage Voltage converter Boost converter circuit MSP430 Microcontroller Constraints: High voltage control Technology: Scaling down by a factor about 4 (90 series cells to 24 series cells) Market Survey Commercially available switching mode power supply for electric vehicles is offered by Brusa. The NLG5 provides a high voltage power source from a 120V or 240V wall outlet. Cost: over $2,000 Brusa does not have a Battery Management Systems. NLG503-light battery charger. 1.6 kW 200-540V, $2,145 Risk Electric Shock: The risk of electric shock is possible when working with a charging system. System Component Damage: As power is being applied and the charging system is running, the risk of overheating, voltage/current spikes, and incorrect connections are possible. Mitigation Testing and Simulation: To prevent component damage and ensure proper design, the system will be modeled to test for expected results. Lower Volt System: With the 42V – 86.4V scaled down system, the risk a shock is reduced. Smart and Safe: By knowing how to be safe and building the system with human/component safety in mind will aid in avoiding risk. Project Plan Milestones and Schedule Cost Breakdown Total: $520 Total: $2120.00 System Design Functional Decomposition (Hardware) Functional Decomposition (Software) Large Scale design Small Scale Design UCC28019AEVM Boost Circuit Will supply the needed maximum 324 volts to the buck circuit for the large scale charger 350 W Power Factor Correction (PFC) boost converter 390 VDC regulated output 0.9 A of load current Advanced fault protection Buck circuit and Feedback Loop The buck circuit will take the voltage generated by the boost buck down to cells The negative feedback loop Scaled down buck circuit Negative feedback tends to compare actual voltage with desired voltage and seeks to reduce the difference Inductor 100uH Capacitor 330uF Value of components Battery Management System Will use TI’s processor bq76PL536EVM-3 and Aardvark USB-SPI adaptor EVM-3 will monitor, balance and charge 24 cells in series Will use Aardvark to gather the packet of information and display in the PC using using Evaluation software Implementation of the bq76pl536 with 24 series cells Software Technology Platform • Use Ti’s Evaluation software to monitor the status of batteries Test Plan Subsystem test: • Boost Converter • System DC supply • Buck Converter with MSP430 Launch Pad • All necessary voltages and currents with PWM • Battery Management System communication • USB-SPI Processing GUI (PC) • Ability to control feedback loop from MSP430 to buck Integration Test (scaled down): • 24 cell charge/discharge • 48V-86.4V CC (up to 3A), 86.4V CV until 0.3A Prototype Implementations & Results Coding for the MSP430 PWM output and ADC has been completed Basic resistor divider input has been implemented to changed the PWM duty cycle Components for the buck converter have been sourced Current Project Status Task Distribution System Design Buck Converter-Matt, Hao Boost Converter-Matt, Jimmy Battery Management System-Pramit, Matt Jimmy, Hao Plan for Next Semester Obtain parts and evaluation module from TI Use what we can to quickly expand the scaled down version. • Series PCB • Use single evaluation module Implement the buck converter. Implement communication between the evaluation module and the MSP430 Display charging information with a pc Questions ?
