Transcript Wind and solar hybrid power - Florida International University

SOLAR AND WIND HYBRID
POWER SYSTEM
TEAM #20
Andre Siuffo (3914666)
Kevin Gregorio (2085117)
Marisol Contreras (2890694)
EML 4551 – Senior Design Organization Class
Mechanical and Materials Engineering Department
Florida International University
Introduction and Goals
Purpose
• Design a small hybrid
electric system
• System combines
both wind electric
and solar electric
technologies
• Able to deliver 1500
watts of continuous
power
Goals
• Product can be
developed for about
$1000
• Stimulate new
companies to offer
the same product for
less
• Design improvement
The Product
What it can power
•
•
•
•
•
•
Refrigerator (600 watts)
Several Lights (400 watts)
TV (200 watts)
Computer (250 watts)
Portable Heater (1300
watts)
Wide Range of Medical
Equipment (7-350 watts)
Composition
How does it work
•
•
•
•
•
•
Wind Generator
Solar Panel
Charge Controller
Battery
Inverter
Solar panel and wind turbine
will charge the battery through
the controller
•
Inverter will be used to convert
power from the battery into
power suitable for domestic use
•
System will have a battery bank
Design Improvements
 Portable
• Less than 10 feet when not in operation
• Reach an optimal operational height
• “Plug & Play” – Quick Installation
 Blade Design Optimization
• Seek information from department
• Materials
• Angle of Attack
 Rotating Solar Panel
• Solar tracker implementation (360
degrees rotation around tower)
Standards
The design and installation of this product must in accordance with applicable codes and standards such
as:
•
•
•
•
•
•
•
NEC (National Electric Code)
IBC (International Building Code)
EIC (International Electrotechnical Commission)
ANSI (American National Standards Institute)
ISO (International Organization for Standardization)
US/SI (US and International Systems of Units)
NPS (Nominal Pipe Size)
Global Learning / Global Design
 Design for manufacturability in different parts of the world
•
Easy to source components both locally and internationally
 Cost analysis for different regions and in different currencies
•
Cost depends on location.
•
Product Development and Production: North America (Miami), South America (Brazil), Asia (Vietnam)
 Multi-lingual user’s manual and assembly instructions
•
English, Spanish, Portuguese, French, Vietnamese and Arabic
 Manufacturing drawings in both US and SI units
•
ANSI and ISO drawing standards.
 Warning labels
•
Multi-language and graphical warning
Responsibilities
Andre Siuffo
Kevin Gregorio
SUPPORT
SUPPORT
Marisol Contreras
Project Formulation
Literature Survey
Design Research
SUPPORT
Conceptual Design
Initial Design
SUPPORT
CAD Drawings & Simulation
SUPPORT
Material Selection / Costing
SUPPORT
Assembly
Product Testing / Analysis
Final Design
SUPPORT
SUPPORT
Project Timeline
August
Project Formulation
Literature Survey
Design Research
Conceptual Design
Initial Design
CAD Drawings & Simulation
Material Selection / Costing
Part Acquisition / Assembly
Product Testing / Analysis
Final Design
September
October
November December
January
February
March
April
Economical Benefits
1. Wind and Solar turbines are cost effective.
•
Standard off the shelf inexpensive materials
•
Easy to manufacture – Low cost manufacturing
2. Stop or reduce the monopolization of power companies.
3. Can be built and used in rural and farm areas.
Environmental Benefits
1. Design is made of recyclable materials.
2. No Pollution since using natural resources for energy (wind and sun).
3. Saves Earth’s resources in making energy (no wood, coal, oil and gas
needed).
Solar & Wind Hybrid Power System
PROBLEM STATEMENT
DESIGN OBJECTIVES
• If any phrase were to be used to describe the time in
which we are living, it would be “renewable energy.”
• For decades now, this term has caused many
businesses to design and manufacture products in
efforts of promoting this phrase.
• Cost and ease of transportation, however, is the
biggest problem these companies are facing.
• Design a system that combines both wind and
solar technologies.
• Deliver at least 1500 watts of continuous power.
• Reduce cost to stimulate the industry to offer
similar products at lower prices.
• Optimize the efficiency of the system.
MOTIVATION
SYSTEM COMPONENTS
• Develop a power solution for remote locations
such as rural and research areas.
• Improve the general well-being of individuals in
developing countries.
• Provide a temporary relief to locations affected by
natural disasters.
• Achieve low-cost energy generation.
• Wind Turbine – Power Generator
• Solar Panel – Power Generator
• Charge Controller – Ensures charge goes in one
direction
• Battery – Energy storage
• Inverter – Converts power stored in battery into
power suitable for domestic use.
TEAM MEMBERS
Faculty Advisor:
Dr. Sabri Tosunoglu, Program
Director
Andre Siuffo
Kevin Gregorio
Marisol Contreras
TIMELINE / RESPONSIBILITY
August
September
October
November
December
January
February
March
Project Formulation
SUPPORT
Literature Survey
SUPPORT
Design Research
SUPPORT
Conceptual Design
Initial Design
SUPPORT
CAD Drawings &
Simulation
SUPPORT
Material Selection /
Costing
SUPPORT
Part Acquisition /
Assembly
SUPPORT
Product Testing /
Analysis
Final Design
SUPPORT
HOW IT WORKS
Andre Siuffo
April
Kevin Gregorio
Marisol Contreras