PrimoPyro1990

…. Composite Rocket Fuels ….

DISCLAIMER: The following file contains information of harmful or illegal
nature. Neither the
BBS or author providing this information
can be considered responsible for the use of this
file.
The person using this knowledge is solely responsible for
it’s use or misuse.
This file is intended to educate only.

1.) Introduction

Composite propellants are solid rocket fuels that are composed of separate
fuels and oxidizers
mixed together in one homogenous mass. This propellant
is then either molded into a grain to
be inserted in an engine or cast in an
engine casing and left to harden. The fuels and
oxidizers taken separately
are generally unreactive. Composite propellants are used in a
number of
engines. There are engines that use water for fuel and an oxidizer, air for
an
oxidizer like a ramjet, and a liquid/solid engine that can be throttled.
The rocket motors
discussed here a best built by the amateur with propellant
weights below 2 lbs. and preferably
under 1 lb. This is still powerful enough
to shoot a sizable rocket to well over 4 miles
altitude.
Before I get into propellant mixtures a few terms to learn are:
Specific
Impulse – Defined as the impulse (force * time) delivered by
burning a unit weight of
propellant in a rocket engine.

Volume Specific Impulse – The product of specific
impulse and density. This
is expressed in pound-seconds per cubic inch.
If the
propellant’s weight is kept constant, a
propellant with a lower Isp but a higher density

may outperform one with a greater Isp but a
lower density.

Specific Force – This
is a measurement of the ability for a gas to perform
work. Specific force (F) is expressed in
foot-pound per
pound.

3.) OXIDIZERS

Composite propellants
contain both an oxidizer and a fuel. The oxidizer may
be a monopropellant and as such
contributes power to the propellant mix.
The ideal oxidizer should decompose into totally
gaseous exhaust.

Oxidizers used in composite propellants : Potassium perchlorate
(KClO4).
Potassium pechlorate was one of the first used oxidizers. One of it’s draw-

backs is the product of decomposition ( potasium chloride ) is not a gas at
regular
temperatures and does not contribute as a working gas. The KCl
appears as a dense smoke in
the rockets exhaust. Burning rates of propellants
made with KClO4 are usually high at 0.8 –
0.9 in/sec at 1000 PSI. Densities
of fuels made with KClO4 also tend to high at 1.8 – 2.0
gm/cc. Specific
impulses are usually below 200 lb-sec/lb. Potassium perchlorate is hardly /> ever used im modern propellants.
Ammonium Perchlorate NH4ClO4. This is the oxidizer of
choice when possible.
The products of diassociation of NH4ClO4 are 100% gas. The specific
impulse
of propellants using this oxidizer reaches 250 lb-sec/lb. Depending on the

percentage of NH4ClO4 the burning rate may reach or exceed 0.5 in/sec. The
products of exhaust
are N2, CO, CO2, H2, H2O, and HCl. The HCl may pose some
problem if the engine is used in high
humidity as the HCl vapor may form
visible hydrochloric acid fumes.
Ammonium Nitrate
NH4NO3. This oxidizer is useful as it is usually available
in bulk weight. The products of
disassociation of NH4NO3 are 100% gas. How-
ever the temperatures produced by the propellant
are low. For this reason,the
specific impulse of NH4NO3 propellants are usually no greater
than 180 lb-sec
/lb and low percentage propellants have an Isp of 75 lb-sec/lb. The
products
of exhaust of NH4NO3 propellants are N2, CO, CO2, H2, H2O. These gases cause
no
special problems. The burning rate of NH4NO3 Propellants are low, ranging
from 0.05 in/sec to
0.27 in/sec. The higher burning rates are possible if
catalysts are used in the propellant.
Prussian blue, chromium compounds
(ammonium dichromate), or cobalt compounds are catalysts
that are used.
Ammonium nitrate is hygroscopic and undergoes a phase change if the temper- /> ature goes above 90 deg./F. Because of this phase change, some grains may
crack if the
temperature cycles about this temperature. The burning temper-
ature of NH4NO3 propellants are
lower than any other propellants especially
at low percentages of oxidizer.
Lithium
Perchorate LiClO4. Some work has been done using lithium perchlorate
as an oxidizer. The
lithium chloride formed in the exhaust is a gas at high
temperatures. Lithium salts are
hygroscopic and must be protected from high
humidity. Burning rates of LiClO4 propellants are
similar to KClO4 mixtures.

4.) FUELS

Fuels Used in Composite Propellants :
Since most rubbers and polymers are not
available to the general public, some adjustments have
to be made. A good
source of plastics is an auto supply store. There you can find epoxy
resin
which can be used as a fuel. You will also find fiberglass resin. This is a
liquid
made from polystyrene and polyester resin. It is catalyzed with a few
drops of hardener. PVC
plastic can be dissolved in tetrahydofuran to make
a thick paste. This can be mixed with an
oxidizer and allowed to dry for an
extended time to form a propellant grain. Asphalt was used
in some JATO units
about 30 years ago but it was found lacking when used at high
temperatures.
Some fuels used in commercial engines are polyurethane rubber, polysulfide

rubber, and butadiene-acrylic acid. Non ferrous metals are added to propell-
ants to increase
the temperature of combustion and consequently the Isp. The
metals most used are aluminum,
magnesium, and copper. The metals are usually
added in amounts of 5% – 25%. In engines
designed to breath water as an oxid-
izer, metal amounts to about 50% to 80% of the weight of
the propellant. The
other components are usually ammonium perchlorate and a polymer.
/> Propellant Grain Geometry : If the grain is ignited from end on, like a
candle burns, the
thrust will be steady or neutral. If the grain has a hole
in it extending end to end and the
combustion takes place from the inside out
then the thrust will rise to a peak or be
progressive. This is because the
surface area of the grain becomes greater as it burns whereas
in a neutral
grain the surface area remains the same. A cruciform shaped grain produces a /> large amount of thrust first then tapers off because the surface area becomes
smaller. If
the grain is tubular and the combustion takes place from both the
inside out and the outside
in, then the thrust will be neutral but fast
burning.
Wherever you wish the grain not to
burn, it must be coated with a retardent.
Epoxy works well as a retardent as does Elmers white
glue. At least two coats
of retardent should be used. An epoxy retardent can be used to retain
a grain
in a rocket engine. When tubular grains are used, the igniter is usually put

towards the nose of the rocket and fires backwards towards the nozzle. This
insures the grain
is ignited completely.
Inspect the propellant grain for any cracks or imperfections. A crack
can
cause the surface area of the propellant to increase astronomically. This can
cause
an explosion because of the increased pressure.

5.) PROPELLANT MIXTURES

The ratios of oxidizers and fuels depends on the type of engine desired. The
amount of
oxidizer can be as high as 90% as in some ammonium nitrate mixes to
as little as 20% ammonium
perchlorate as in some water breathing engines.

A fast burning mixture: Potassium
Perchlorate 20%
Isp=200 Ammonium Perchlorate 55%
Epoxy Resin/Hardener 17%
Powdered
Aluminum 8%
This is very fast burning but the exhaust makes a fairly heavy smoke.

A slow burning propellant. Great for sustainer engines.
Isp=165 Ammonium Nitrate 70%

Ammonium Perchlorate 10%
Polyester Resin 18%
Powdered Charcoal 2%
Not very
powerful but useful. The charcoal helps keep the combustion steady.

A very powerful
mixture: Ammonium Perchlorate 75%
Isp=250 Powdered Aluminum 10%
PVC in THF 15%

All the ingredients should be dampened with THF (tetrahydrofuran) before
mixing. Do this in an
area with very good ventilation and wear rubber gloves
to keep from contacting the THF with
bare skin. This mixture is best used in
a perforated grain to help the solvent evaporate. />
An ammonium nitrate based propellant: Ammonium Nitrate 70%
Isp=160 Powdered Aluminum
5%
Polyester Resin 18%
Ammonium Bichromate 5%
Powdered Charcoal 2%
A good
mix when perchlorates are not available.

Do not under any circumstances use chlorates
for rocket propellants. You will
not make a rocket, just a pipe bomb with fins.

6.) COMPOUNDING PROPELLANTS

One thing to keep in mind when making a propellant,
the volume of fuel/binder
to volume of oxidizer and additives must not be too low. If it is
then the
mixture will be too dry to mix well. It will also hurt the strength of the

grain. You may have to cut down on the amount of oxidizer depending on the
fuel you are
using.
For rockets weighing 1 pound and less the easiest way to make the propellant
is
to obtain a suitable container for mixing and put in the bottom of it the
correct amount of
fuel/binder. The other ingredients are added one at a time
to the fuel and mixed in. One
thing that really determines the success of a
propellant is the particle size of the oxidizer.
It should be as finely
powdered as possible. Continue mixing the propellant until it is a
homo-
geneous mixture. Now pour it or stuff it into the engine casing taking care
to
eliminate all air bubbles. Any mandrels needed to form the grain to shape
shpould already be
lubricated for release and in place. After waiting a suit-
able time for the binder to harden,
remove the mandrels and place the engine
in a warm place to finish curing. Inspect the grain
for any cracks or imper-
fections.
Some large propellant grains are constructed by
cementing smaller grains to-
gether. Disks of propellant can be glued and stacked to form a
long grain.
The disks can be drilled with a number of holes to make a progressive or

regressive burning grain. The holes are lined up when the disks are stacked.
If you construct
a press with a number of guide rods to match the drilled
holes, so much the better. The cement
can be a very thin layer of the polymer
used to make the grain. If you are using a PVC based
grain, then dampen both
mating surfaces with THF and press them together for a minute before
adding
the next disk.
You can also load a cardboard casing with the propellant. After
the prope-
llant is cured, this cartridge is loaded into the engine.
When drilling these
propellants or using any power tool for shaping them, use
the lowest speed while checking to
make sure no heat is building up on the
cutting surface. If care is used, machining
propellants is safe.

7.) ENGINE CONSTRUCTION

The typical engine is
designed to operate at 1000 psi. The casing of the
engine should be able to withstand at least
3000 psi as a safety factor. A
low carbon seamless steel tube with 1/16" walls can
withstand that sort of
pressure. If the tubing has a welded seam, test fire a few engines to
see if
the tubes can take the pressure. One drawback to using steel as an engine
casing
is if the engine explodes you have some very lethal shrapnel flying
around. If you use a high
strength/high heat plastic you can eliminate some
of this danger. Epoxy can be used to wet
down a mat of fiberglass then the
fiberglass is rolled around a large dowel to form a casing.
The dowel has to
be coated with a lubricant to keep the epoxy from gluing the casing and /> dowel together. Or you can obtain a heavy cardboard tube with the correct ID
and coat it
with epoxy then wrap epoxy/fiberglass around it. If the tubes are
constructed properly they
can take quite a bit of pressure before splitting
apart.
An rocket engine is equipped
with a nozzle to accelerate the exhaust out of
the rocket at a high velocity. A nozzle has a
convergent section that does
this. A divergent section of nozzle is used to lower the exhaust
pressure
so the exhaust gases accelerate out of the engine at high speeds.
The nozzle of
the engine can be machined out of metal or made of a fireproof
ceramic. If the nozzle and the
casing are metal, they can be brazed together
before the engine is loaded. The nozzle can also
be screwed into place by
using 4 – 6 screws going through the side of the casing into the
nozzle. Care
must be used to see that the screws don’t break through the inside of the

nozzle. On smaller rockets, you may be able to get away with plaster of paris
nozzles or for
more powerful motors try pressing a mixture of 90% kaolin and
10% aluminum oxide into a nozzle
shape in the casing. Dampen the mix with a
little water before pressing. You can make a nozzle
die by turning 2 pieces
of hardwood into divergent/convergent sections. This die should be
fitted
with a dowel guide pin at the mating points to help keep the die straight.
A
nozzle can be made from just a divervent section. This can be easily made
by drilling the
required hole in a section of nozzle. Then by drilling out
the first hole with larger drills
without completely breaking through, a
diverging nozzle is formed. Smooth out the ID of the
nozzle after drilling
the holes. This type of nozzle is pretty good on smaller engines with a
1" ID
or less. By using some ingenuity, you should have no problem in making a

servicable nozzle. A rule of thumb to use for the ID of the nozzle is to use
a hole that has
an area (repeat-area,not diameter) 1/3 the area of the ID of
the rocket engine casing.

Most propellants burn unsteadily at low pressures. Solid rocket engines are
equipped with a
blast plug that allows the pressure to build up in the engine
before being blown out like a
cork in a bottle. Sometimes the ignitor is
combined with the blast plug in a single unit. A
stiff plastic disk makes for
a good plug. It should have a thickness of about 1/16". /> The engine is sealed with a plug in the fore section. Depending on the con-
struction of
the engine this plug may be made of wood, plastic, or metal. It
is held in place with either
screws or epoxy. This plug must make the casing
gas tight. Remember most rockets develop 1000
PSI.
The ignitor is simply an electric match. It can be made with nichrome wire
or a
small light bulb. The match is used to ignite a small charge of black
powder that in turn
ignites the propellant. The ignitors leads should be
shunted together to eliminate premature
ignition. A fuse can be used instead
of electric ignition. If you go this route, be sure of
the burning time of
the fuse and allow yourself enough time to retreat to safety after
igniting
the fuse. I cannot recommend using a fuse because you cannot stop a fuse
from
burning if someone walks into your launch area. With electric ignition,
everything is under
your control until the time of launching.

8.) Engine Design

It would be
nice to be able to give you the complete info on designing
rocket engines. However, the
required math would be a file about 300K in
length. Also this file is mainly about
propellants. The other info is gravy.
The best I can offer is to check out your local library
for design
and engineering books. If you want to build a rocket to simply shoot off to

stroke your pyro perversions, build a small engine containing no more than
4 oz. of fuel. Use
a paper casing to keep the danger down and chances are
very good that if your construction is
sound you’ll get the thrill of seeing
your rocket go out of sight. If you plan to hoist a
payload into suborbital
projectory however, learn about thermodynamics, interior ballistics,
and
propellant chemistry.
I recommend trying to get the book Amateur Rocketry Handbook.
This
book is out of print but it was put together by the Fort Sill Artillery
School and
contains a lot of valuable info.

9.) Testing and Firing

You should
construct a few engines exactly the same and test fire a
number of them to find out what to
expect when you finally do launch a rocket
. The engines can be buried nozzle end up in the
ground and fired. Time the
burning of the engine to figure out the rate of combustion of the
propellant.
Inspect the casing to see how it stood up. If everything seems okay you can

construct a static testing fixture to measure the thrust. Keep in mind that
even a small
engine can put out a few hundred pounds thrust for a split
second. When you do launch a
rocket, keep people away from the launch site
and under cover. Check out the skies for
airplanes or other traffic. Don’t
launch rockets under conditions of low visibility or heavy
winds.

*** Kilroy was here ***



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