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Autonomous Vehicle Design

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Title: Autonomous Vehicle Design


1
Autonomous Vehicle Design
  • Florida Tech AIChE
  • 1999
  • P. Engel, T. McKenney, M. Mensch

2
Reaction Selection
  • The optimum propellant to use for the
    autonomous vehicle would be one that has a high
    thrust and a low production cost. The simplest
    and most obvious choice would be to use a solid
    rocket propellant. The rocket propellant chosen
    has a high burn rate and relatively clean
    exhaust. A high burn rate propellant will yield
    a very high initial thrust, this will overcome
    the coefficient of static friction quickly and
    effectively.

3
The Reaction
  • NH4ClO4 (s) Mg(s) CuO MgO(s) MgCl2
    (s) NO(g) H2O energy
  • NH4ClO4 (ammonium perchlorate) oxidizes the
    metallic fuel (magnesium) in the presence of a
    burn-rate catalyst (copper oxide).
  • The majority of the product formed is water vapor
    and magnesium chloride.

4
Laboratory Requirements
  • Vacuum Chamber
  • Needed to remove unwanted gases formed during
    mixing.
  • Makes the composition more uniform.
  • Mixer
  • Needed to obtain the desired propellant
    composition.
  • Reduces the presence of temperature gradients
    during heating.
  • Heating Pad
  • Needed to reduce the viscosity of the propellant.
  • Reduces the amount of work on the mixer
  • Process Controller
  • Needed to regulate the temperature within a
    specific range.
  • Keeps the heater from overheating the propellant.

5
Experimental Procedure
  • First HTPB, the binder, is added to the bowl and
    heated to 55 C while mixing.
  • Next magnesium, the metallic fuel, and copper
    oxide, the catalyst, are added appropriately and
    mixed until uniform.
  • Finally ammonium perchlorate, the oxidizer, is
    added, the power is turned off, and the mixture
    is placed into the vacuum chamber.
  • The vacuum pump is engaged, when pressure
    stabilizes then the power to the mixer and heater
    is turned on.

6
Experimental Procedure
  • After the mixture has been in the vacuum chamber
    for 30 minutes, the pressure is removed slowly
    and diphenylmethane diisocyanate, the curing
    agent, is added.
  • The mixing is continued until the mixture is
    homogenous, then the heating source and mixer are
    turned off.
  • The propellant is then removed, placed into
    molds, and left to cure.

7
Environmental Considerations
  • The most widely used fuel in solid
    propellants is aluminum because it offers a
    better burn. The downside of using aluminum is
    that after combustion it yields aluminum
    chloride, this then hydrolysis and produces
    hydrochloric acid (HCl). Hydrochloric acid will
    corrode metals and lower the pH of the
    environment in which it comes in contact with.
    Therefore we chose to use a magnesium fuel, which
    yields magnesium chloride. Magnesium chloride is
    found in large quantities in the ocean and does
    not cause any environmental problems, nor does it
    form an acid.

8
Exhaust Evaluation
  • The propellant chosen had a very clean burn,
    resulting in a very low smoke content. The
    exhaust consists mostly of water vapor and small
    quantities of nitric oxide. Nitric oxide is a
    lung irritant, but since the reaction only
    produces a very small quantity of this, the
    hazards related to it can be neglected. Other
    products that may be produced are oxygen (O2),
    nitrogen (N2), and hydrogen (H2). The Earths
    atmosphere consists of nitrogen and oxygen, these
    two elements are stable in the diatomic form.
    Hydrogen is highly flammable and therefore will
    only add to the propulsion flame.

9
Explosion Safety
  • To prevent the rocket engine from becoming a pipe
    bomb, an aluminum nozzle was used. Aluminum is a
    relatively soft metal and therefore will yield if
    enough pressure is applied.
  • This became the downfall of the design. After a
    number of tests, the threading on the nozzle
    became weak and gave out. The nozzle was
    projected out of the back end of the engine, and
    rendered useless for further tests.

10
Nozzle Design
  • Aluminum Metal Material
  • Easier to machine than steel.
  • Resists melting and corrosion well.
  • Safer to use as a nozzle than steel.
  • Necessity of Nozzle
  • Controls the pressure drop through the end of the
    engine.
  • Focuses exhaust and increase exhaust escape
    velocity.
  • Size of Nozzle
  • Nozzle throat should be 1/3 surface area of pipe
  • 3/8 engine requires nozzle diameter of 0.217 in,
    since this diameter could not be machined a 1/8
    diameter was used.

11
Chassis Design
  • Carbon Fiber Chassis
  • Heat and explosion resistant
  • High mechanical strength
  • Low body weight
  • High Grip Wheels
  • Increases traction
  • Flat Bed Body
  • Practical for carrying load

12
Rocket Engine Design
  • Carbon Steel Material
  • High mechanical strength.
  • Heat and explosion resistant.
  • Variable Length Piston
  • Able to use one engine for any amount of
    propellant.
  • Heat Resistant Rubber Coating
  • Adds friction between rocket engine and chassis

13
Ignition Design
  • Electrical Ignition
  • Ran a current through a highly conductive metal
    to ignite the fuel.
  • Safer than using a fuse.
  • More professional.
  • Mounted Ignition
  • Allows ignition source to be placed directly in
    the engine.
  • Increases ignition success.

14
Vehicle Budget
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