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Team Name :. Project Title : LSV2 (Large Scale Vehicle) Autonomous Battery Charger. Team Members : Branden Carpenter EE Senior Jon Stoker CS Senior Maggie Richardson EE Senior Wayne Romine EE Senior. Our Sponsor. Initial Specifications _.
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Team Name: Project Title: LSV2 (Large Scale Vehicle) Autonomous Battery Charger Team Members: Branden Carpenter EE Senior Jon Stoker CS Senior Maggie Richardson EE Senior Wayne Romine EE Senior
Initial Specifications _ • Must remotely access the battery chargers • Including all displayed values such as: • Fault Indicators • Displayed values for Current and Voltage • As well as providing control capability: • Ability to change voltage and current levels • Have an emergency stop function • Graphical user interface mush be easy to understand/use • Remote control function must have a PC control option • Charging algorithm will be implemented in later project • Separate control unit will be able to implement the charging algorithm • Unit will also act as a backup if there is a computer failure • Design must use the current control board installed in the charging units • Units have a local remote switch that utilizes a PCB housed inside the charger
Preliminary Results • From initial research the RS-485 pin connection on the PCB inside the charging unit will likely be the point of control. • A microcontroller will need to be employed to display and control the charging units remotely. • A separate box will be created to handle the control and display of information. • PC control will be added at a later time • Although this box should be able to operate indecently, connections for the PC will be an important element to our design • A optimum charging profile was designed for a previous Senior Design project. • This profile will be used to create a charging algorithm that will automate the charging process. • Commercial embedded controllers exist but our team should be able to design a more economical solution for our client. • The Client presently has a system that displays the battery charging level. Connection from that system will provide a feedback loop for the charging algorithm implemented via a PC.
Problem Statement • Presently a battery technician monitors screen displaying the voltage and current levels being sensed in the seven battery strings comprising the LSV2 battery bank. • Once a condition requiring action is reached, the technician must leave the computer workstation and adjust analog knobs located on the front panel of the charging units. These units are installed in a different location of the moorage facility. • Once the alteration is manually set on the charging unit, the technician returns to the workstation to check that the desired effect begins to take place. • This process is repeated for each of the seven charging units at specific points in the charging process. • The optimized profile could be better implemented if the charging profile of each battery sting are controlled autonomously. • Our team proposes to design a configuration that allows the chargers be controlled remotely, specifically at the workstation that monitors the charge. • With this capability it is then possible to automate the entire process and control it from any location connected to the monitoring workstation.
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Initial Controller Conceptual Design Charger #1 #2 #3 #4 #5 #6 #7 C: V: Fault Indicators Input Current Enter Current Charger # 0000.00 UP Input current value DN Input Voltage Select charger Enter Voltage 0000.00 UP Input voltage value DN Local /PC Toggle Switch