client: city of breda/breda municipal electric system advisor: james d. mcalley
DESCRIPTION
Senior Design: Team SD1101. Client: City of Breda/Breda Municipal Electric system Advisor: James D. Mcalley Team Members: David Mindham (EE), Rui Bai (EE), Anthony Tong(EE), Christopher Krantz (EE. TEAM NAME: “BREDA TRANSFORMERS”. Overview Project Plan. Problem Statement - PowerPoint PPT PresentationTRANSCRIPT
Client: City of Breda/Breda Municipal Electric systemAdvisor: James D. McalleyTeam Members: David Mindham(EE), Rui Bai(EE), Anthony Tong(EE), Christopher Krantz(EE
Senior Design: Team SD1101
TEAM NAME: “BREDA TRANSFORMERS”
Overview Project Plan
Problem Statement Conceptual Sketch Functional Requirements Non-functional Requirements Technical/Other Constraints/Considerations Market survey – articulate what makes your
project unique Potential Risks & Mitigation Resource/Cost Estimate Project Milestones & Schedule
Problem Statement
Create a functional one-line diagram using ETAP software
Collect, research, and report economic analysis of companies providing power to city of Breda
Advise and educate city of Breda on alternate sources of energy and money saving techniques
Concept Diagram
Market Survey
Phase 1 development of small town model power distribution system
Understand costs associated with small towns in Iowa
Economic Analysis Design Collect cost data for the following
areas: Generation, Transmission, Distribution, and Regulation.
Many costs are hidden. Once cost breakdown is complete,
we’ll know which areas we can have the greatest impact.
Cost Analysis
Generation Charges: MEAN and WAPA
Demand Charges: MEAN and Midwest ISO
Transmission Charges: MidAmerican and Midwest ISO
Functional Requirements One-line diagram of the power distribution system of Breda
Power analysis Harmonic distortion analysis Loss analysis
Model Requirements 7.2/12.74 kV 3 MW peak input power Primary line: 1 aluminum conductor steel reinforced(ASCR) Secondary line: 4 ASCR Transformers type: Liquid immersed Motors: 120-250 HP Line impedances
Non-Functional Requirements Safety
Electrical Travel
Team work Reliability Alternative energy IEEE Standards Power Factor Maintenance: +/- 5% of unity. Cost Effective Upgrades: All suggested improves
must pay for themselves in 15 years. Non Technical Document: All reports must be
easily understood by a non engineer (City Clerk.)
Constraints/Considerations Team learning how to use ETAP ETAP data is only as good as the
model developed Data for model continually requiring
updates Length of conductors Types of fuses
Technology
ETAP Power Distribution Analysis Software Provided by Iowa State University
Risks and Mitigation
Resource Cost Estimate
ETAP provided by Iowa State University: No Cost
Task Breakdown and Milestones (Updated)
Task Break Down (old)
Overview System Design
Functional Decomposition Detailed Design (functional modules design,
interface definition, user interfaces, etc.) HW/SW/Technology Platform used Test Plan – simulation, what tests, what
metrics, hypothesis, etc. Prototype Implementations or Basic building
block implementations (and applicable results)
Schematic Diagram
Detailed Functional Design 3-phase 7.2/12.47kV Single phase distribution lines 120/240 V Peak power of 1.2 MW Primary lines Aluminum conductor’s steel
reinforced (ACSR) type 1 Secondary lines type 4 ACSR 37 buses single phase 11 industries and business 3-phase power Capacitor bank, fuses, meters, and switches Motors 100 – 250 HP
Functional Decomposition Unbalanced load flow analysis Motor starting analysis Reliability assessment analysis
Prototype Implementations
Test Plan
Current Project Milestones
Contribution
Plan Aug-Dec 2011
Finish ETAP model 09/13/11 Begin Analysis 9/13/11 Finish Cost Analysis 11/15/11 Finish research on alternative energy
12/01/11 Finish reliability assessment
12/01/11 Compile total information and
present to client
Questions
Sources