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Hovercraft Design

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use acceleration and jerk for fun. Briggs and Stratton Engines. HP, RPM and price ... enthusiastic about the lab and interested in the hovercraft ... – PowerPoint PPT presentation

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Title: Hovercraft Design

1
Hovercraft Design
TEAM 1
2
Introduction
Team Members Brandon Fichera Dave Rabeno Greg
Pease Sean Gallagher
Sponsor Dr. Stephanie Wright Delaware Aerospace
Academy Advisor Dr. Michael Keefe
Mission Statement To design a two person
hovercraft for the Delaware Aerospace Academy
that will demonstrate the scientific principles
of a hovercraft, foster teamwork between
students, and provide a fun, safe, and
educational environment for all students involved.
3
Summary

Introduction
Team, Sponsor, Advisor
Problem/Mission Statement
Background

Concept
Generation
Selection

Customers, Wants,
Constraints
Benchmarking
System
Functional

Concept Development
Test Results, Modifications
Recommendations
Prototype Evaluation

Budget
Construction hours
Engineering Hours
Prototype Cost

Metrics
Target Values

4
Problem Background
Delaware Aerospace Academy

Sponsor of past UD senior design projects.
Specializes in teaching kids about technology
involved in the space program.

Hovercrafts

New and exciting technology that has yet to be
widely distributed.
Interesting tool for teaching scientific
principles
to children

5
Customers

DAA
Dr. Stephanie Wright
Robert Bloom (Aerospace Engineer)
Students
High School Students
Junior High School - Eric Rabeno
Middle School - Ted Elizabeth Pease
Teachers
High School - Martin Rabeno
Junior High School - Selina DiCicco
Industry
Ron Perkins - Educational Innovations
School System
Mark Ellison - Principle High/Jr High School

6
Wants

Educational
Demonstrate Hovercraft Principles to Children

Recreational
Make it fun, Cool Looking

Operational
- Maneuverable - Durable
- Reliable - Transportable
- Reproducible

Economical
- Low Cost

7
Constraints

Size of door in Spencer Lab (4.5 by 6.3)
Allowable Funds (2000)
Number of pilots (must be 2)
Operation (must be able to hover)

8
System Benchmarking

Triflyer - Hovercraft Design
Pegasus - Hovercraft Design
Universal Hovercraft - Hovercraft Construction
Kits
Hover Club - Hovercraft Articles
Science Project - Laboratory Experiments

9
Functional Benchmarking

Smithsonian AirSpace Museum
use videos to excite peoples interest
Six Flags Amusement Parks
use acceleration and jerk for fun
Briggs and Stratton Engines
HP, RPM and price
Elibra / Hovertech
Magnetic levitation

Grainger Industrial Equipment
Electric Motors
RPM, HP and price
Universal Hovercraft
Fans for personal hovercrafts
Northern Tool and Equipment Co.
Gas Motors, price comparison

10
Metrics Corresponding Target Values
1) Number of Principles Taught - 3 2) Performance
on lab experiment - average score 80 3) Height
of hovering (Object Clearance) - 6 4) Skirt to
ground clearance - 1/2 5) Speed of Vehicle - 5
- 10 mph 6) Acceleration - 1 mph/s 7) Directions
of Horizontal Travel - 360 degrees 8) Travel
Range - limited by fuel capacity alone 9) Turning
Radius - 15 ft 10) Fuel Efficiency/Capacity - 3
1/2 hrs 11) Cost - 2000 12) Weight - 1000 lbs.
11
Concept Generation Evaluation Against Metrics
What are the different aspects of our project?
Education, Operation, Recreation How can we
satisfy our mission statement in various ways?

Education Recreation
1) Smithsonian Approach use a video or
descriptive poster to explain the principles to
the children
2) Amusement Park Approach - just let children
operate it and then attempt to explain how it
works
Operation
1) Means of Lift 2) Power Supply
3) Thrust
Magnetic Levitation Electric
Engine/Fan
Fan(s) and Air Cushion Liquid Fuel
Human Power
Suspension Fuel Cells
Rocket Thrust

12
Concept Generation Evaluation Against Metrics

1) With regard to Education Recreation
- Choose Smithsonian Approach
- videos and posters allow for easy
explanation
2) With regard to Operation
- Choose a fan/motor lift and thrust system
- Magnetic Levitation too expensive
- Suspension System too bulky, doesnt
demonstrate hovering principles
- Human Power for thrust is a viable
alternative
- Choose Liquid Fuel
- engines are relatively inexpensive
Doesnt demonstrate appropriate principles
Choose Fans and Air Cushion

13
Concept Selection Mathematical Models (Lift)
Steady-Flow Energy Equation
Bernoullis Equation
14
Concept Selection Mathematical Models (Lift)
From Energy Equation
From Bernoullis Equation
15
Concept Selection Mathematical Models (Lift
Thrust)
W 1000lbs. (from Metrics)
l 10 ft
w 6 ft
Pressure Required 0.116 psi
W 1000lbs. (from Metrics)
a 1.5 ft/s2 (from Metrics)
go 32.2 ft/s2 (from Metrics)
Thrust Force Required 60lbs.
16
Final Concept Selection
1) Educational Poster (education) a)
Discusses uses of Hovercraft as it relates to the
Delaware Aerospace Academy b)
Discusses Construction Design c) Explains
principles of - Lift - Thrust 2) Laboratory
Experiment (education) - Students learn about
lift first hand - Hands on approach similar to
Smithsonian museum 3) Prototype Hovercraft
Demonstration (fun) - Students get to operate a
working hovercraft
17
VIDEO
Hovercraft Specs. Shape Rectangular (10 x 6)
- most stable - ease of construction Fan
System Lift - 8 hp lift engine - 4 blade
26 diameter fan Thrust - 3.5 hp thrust -
2 blade 34 diameter fan Weight - empty weight
of 450 lbs.
18
Lift Test Results
19
Test Results Education

Lab
Experiment and laboratory model brought into
classroom and demonstrated to a class
All students were overwhelmingly enthusiastic
about the lab and interested in the hovercraft
Students demonstrated understanding of principles
by discussing them
Students wanted to build their own model
hovercrafts. Asked how to build one

20
Modifications