Presentation is loading. Please wait.

Presentation is loading. Please wait.

The Recycling Robot SECON Team B Mid-Term Presentation.

Published byLindsay Bates Modified over 9 years ago

Similar presentations

Presentation on theme: "The Recycling Robot SECON Team B Mid-Term Presentation."— Presentation transcript:

1 The Recycling Robot SECON Team B Mid-Term Presentation

2 Team B Dr. Bryan Jones, Advisor Jeff Brantley Jonathan Bryant Brooke Grantham Kevin Vu SortingXX StorageXX DiscriminationXX NavigationXX

3 Outline Competition Overview Project Division Technical Constraints Practical Constraints Project Timeline

4 Problem Statement Autonomous recycling robot for 2009 IEEE SECON hardware competition 10 Recyclables include: –5 aluminum cans –3 plastic bottles –2 glass bottles Must locate, acquire, sort, and store recyclables on the robot [1].

5 Competition Playing Field Artificial turf Recyclables will be placed on their sides The recyclables arrangement will be the same for each heat

6 Competition Recyclables Image obtained from SoutheastCon 2009 Hardware Competition rules [1].

7 Outline Competition Overview Project Division Technical Constraints Practical Constraints Project Timeline

8 Team Tasks Driving Navigation Boundary Detection Acquisition Target Detection Discrimination Sorting Storage Team A Team B

9 Outline Competition Overview Project Division Technical Constraints Practical Constraints Project Timeline

10 Technical Constraints NameDescription Storage Capacity The robot’s storage compartments must accommodate all 10 containers that will reside on the playing field. Target Discrimination The robot must recognize the containers as being either glass, aluminum, or plastic.

11 Storage Capacity Constraints –Plastic bags cannot drag on the field –Store 10 containers Approach considerations –Number of compartments –Expansion

12 Storage Tradeoffs Three compartments –Necessary for maximum score –More complex Two compartments –Less sorting complexity –Reduces maximum possible score Expanding containers –More room for internal subsystems –More likely to extend outside boundary Fixed containers –Less complex –Limits room for other components

13 Storage Capacity Final Approach –Three storage compartments –Store internally

14 Storage Access Small rear slot for glass bottles First slot on top for aluminum cans Can slot closes for plastic to roll past

15 Target Discrimination Initial Approaches –Camera Complex, dependent upon lighting conditions –Infrared (IR) sensor Sensitive to lighting conditions –Force Sensing Resistor (FSR) Limited sensitivity

16 Target Discrimination Container TypeVoltage* Glass3.17 Plastic2.62 Aluminum0.00 *Using 3.3V scale

17 Target Discrimination Final Approach: –Combination FSR and IR sensor –FSR to detect and differentiate between glass and plastic –Cans detected by IR sensor

18 Mechanical Lift Placement –Middle –Front –Back Lift Mechanism –Pulley System –Stepper Motor

19 Lift in the middle Complexity No storage space –Requires expansion

20 Lift in front Storage room Arms in front –Push items –Past outer boundary TOP VIEW

21 Lift in back Robot drives over item Arms moved inside –Turn at outer limits Storage space lost at the bottom Final Approach TOP VIEW

22 Pulley System Level with ground Complexity Room for cables and pulleys SIDE VIEW

23 Stepper Motor Simplicity Offset with size of motor Final Approach SIDE VIEW

24 Navigation Systematic scanning for all possible target locations perimeter sweeping back and forth

25 Outline Competition Overview Project Division Technical Constraints Practical Constraints Project Timeline

26 Practical Constraints NameDescription Manufacturability The robot must fit inside a 12" X 12" X 18" box before beginning of each round. Sustainability The robot must operate at least 4 minutes on a single battery charge.

27 Manufacturability Allowed to use 18” for L, W, or H 18” Height –Small footprint (12” x 12”) is more maneuverable –Tracks take up 3-3.5” in width –Plastic bottles are 8.7” long –Need more room for bottles to between tracks

28 Manufacturability 18” Width –Plenty of room for bottles to pass between tracks –Containers do not naturally fall in the most optimal arrangement –Must reorient some containers to fill in wasted space due to extra width

29 Sustainability Robot must be able to run for a full round (4 min.) on a single battery charge Battery options: –Lithium-Ion Polymer Small, high energy density Performed well for SECON 2008 team Requires external protection circuitry –Lithium-Ion Also a high-density battery Protection circuitry housed in battery

30 Outline Competition Overview Project Division Technical Constraints Practical Constraints Project Timeline

31 Timeline Sept.OctoberNovember Sorting Storage Discrimination Navigation Integration

32 Summary ProblemApproach Target DiscriminationFSR and IR sensor StorageFixed-size box with three compartments SortingLift-and-dump NavigationSystematic, full- coverage sweep

33 References [1] Institute of Electrical and Electronics Engineers. Southeastcon 2009 Hardware Competition: The Recycling Robot, 2008 August 28, http://hardware.gtieee.org/southeastcon2009/Southeast Con-2009-Hardware-Rules.pdf. Accessed September 16, 2008.

34

Download ppt "The Recycling Robot SECON Team B Mid-Term Presentation."

Similar presentations

First Year Robotics Platform By: Andria Farnham, Adam Selinger, Curtis Langley.

First Year Robotics Platform By: Andria Farnham, Adam Selinger, Curtis Langley.
Competition Challenge Scoring Design Constraints Electrical Aspect Common Challenges Last Year Adaptations Gantt Chart Questions.

Competition Challenge Scoring Design Constraints Electrical Aspect Common Challenges Last Year Adaptations Gantt Chart Questions.
Bad News Bots E2 Ryan Bove Kara Collins Peter Courtney Kyle O’Reilly Benjamin Rowland Concept Design Review.

Bad News Bots E2 Ryan Bove Kara Collins Peter Courtney Kyle O’Reilly Benjamin Rowland Concept Design Review.
Engineering Roles We will be forming groups of 3 students

Engineering Roles We will be forming groups of 3 students
Cambodia Robocon March 2015

Cambodia Robocon March 2015
SOUTHEASTCON I KARMA ECE 4532-04. 2004 IEEE SoutheastCon Hardware Competition Must build an autonomous robot that can –Start at rest at the Starting Station.

SOUTHEASTCON I KARMA ECE IEEE SoutheastCon Hardware Competition Must build an autonomous robot that can –Start at rest at the Starting Station.
Cory Fulkerson (Project Manager) - Mechanical Engineer John Graham - Computer Engineer Clayton Hooks - Electrical Engineer O’Raphael Okoro - Electrical.

Cory Fulkerson (Project Manager) - Mechanical Engineer John Graham - Computer Engineer Clayton Hooks - Electrical Engineer O’Raphael Okoro - Electrical.
The Pied Pipers Alyssa Visitacion Ken Shum Joanne Flores.

The Pied Pipers Alyssa Visitacion Ken Shum Joanne Flores.
Group Members Ikechukwu Mogbana Adewuyi Kupolati Frederick Tyson Advisor Prof. Mahmood February, 16 2006 Senior Project 2005/06 Undergraduate Project Proposal.

Group Members Ikechukwu Mogbana Adewuyi Kupolati Frederick Tyson Advisor Prof. Mahmood February, Senior Project 2005/06 Undergraduate Project Proposal.
M & M EE 296 Final Presentation Spring 2004 Presentation Overview Team Member Introduction Project Overview Overall Design Description Final Project.

M & M EE 296 Final Presentation Spring 2004 Presentation Overview Team Member Introduction Project Overview Overall Design Description Final Project.
Critical Design Review Colorado State University - Pueblo April 15, 2005.

Critical Design Review Colorado State University - Pueblo April 15, 2005.
Team 23: 2013 IEEE ROBOT COMPETITION. Introduction Team 23 – IEEE Region 5 Robot Competition F12-23-EEE1 Client: Ning Weng Team Members: Claudio Copello.

Team 23: 2013 IEEE ROBOT COMPETITION. Introduction Team 23 – IEEE Region 5 Robot Competition F12-23-EEE1 Client: Ning Weng Team Members: Claudio Copello.
NEEDS ANALYSIS & REQUIREMENTS SPECIFICATION Southeast Con 1B “Success” Senior Design Team Louis Cooper Evan Marshall Chelsea Ogle Lorenzo Smith Ivan Vargas.

NEEDS ANALYSIS & REQUIREMENTS SPECIFICATION Southeast Con 1B “Success” Senior Design Team Louis Cooper Evan Marshall Chelsea Ogle Lorenzo Smith Ivan Vargas.
By the end of this chapter, you should:  Understand the properties of an engineering requirement and know how to develop well-formed requirements that.

By the end of this chapter, you should:  Understand the properties of an engineering requirement and know how to develop well-formed requirements that.
Team HazardHawk Team HazardHawk 2008 April 24, 2008.

Team HazardHawk Team HazardHawk 2008 April 24, 2008.
Maple seed sensor housing for desert reconnaissance

Maple seed sensor housing for desert reconnaissance
IS312: information systems theory and applications LECTURE 1:SYSTEMS THEORY AND MAIN CONCEPTS Information Systems Department.

IS312: information systems theory and applications LECTURE 1:SYSTEMS THEORY AND MAIN CONCEPTS Information Systems Department.
All logos in this presentation is courtesy of the Florida Institute of Technology Robotics and Spatial Systems Laboratory and the Florida Tech University.

All logos in this presentation is courtesy of the Florida Institute of Technology Robotics and Spatial Systems Laboratory and the Florida Tech University.
Tony Soprano: “Waste Management” Final Presentation Salvatore Torre 11/25/2008.

Tony Soprano: “Waste Management” Final Presentation Salvatore Torre 11/25/2008.
To come up with a practicum project that full filled the 411 requirements Create a fun project that would get kids interested in science and engineering.

To come up with a practicum project that full filled the 411 requirements Create a fun project that would get kids interested in science and engineering.

Similar presentations

Ads by Google