- 1.CONSTRUCTION OF A MODEL LIQUID FUELED ROCKET ENGINEALEJANDRO
ALJURE OSORIOUNIVERSIDAD DE LOS ANDES FACULTY OF ENGINEERING
DEPARTMENT OF MECHANIC AL ENGINEERING BOGOTA D.C., JANU ARY
2007
2. CONSTRUCTION OF A MODEL LIQUID FUELED ROCKET ENGINEALEJANDRO
ALJURE OSORIO Cod. 200125087Thesis project presented to obtain the
Bachelor of Science in Mechanical EngineeringAd visor FABIO A.
ROJAS Dr. Eng.Mec.UNIVERSIDAD DE LOS ANDES FACULTY OF ENGINEERING
DEPARTMENT OF MECHANIC AL ENGINEERING BOGOTA D.C., JANU ARY 2007 3.
ACKNOWLEDGEMENTS I wish to thank Fabio Rojas, who as a professor
and advisor guided me through a great part of my undergraduate
studies. Also for the great interest he showed in the rocketry area
and the will to work on it. I would also like to thank Mateo,
Ramiro, Jorge and the rest of the staff of the Mechanics Lab, for
their patience and help in the construction of the rocket engine.
4. Dedicated to my parents Eduardo and Gloria for everything they
have gi ven me and the faith they had in me. To my brothers, my
grandparents And all my family, especially my family in Bogot, for
helping me getting settled in the city and being there when I
needed help 5. IM-2006-II-01v TABLE OF
CONTENTSINTRODUCTION.......................................................................................................................7
PROPERTIES OF LIQ UID
PROPELLANTS..............................................................................
10 P HYSICAL
PROPERTIES..............................................................................................................
10 C OMBUSTION
PROPERTIES.........................................................................................................
11 S TART AND
IGNITION...............................................................................................................
11 DESIGN EQ
UATIONS..............................................................................................................
13 NOZZLE
................................................................................................................................
14 C OMBUSTION CHAMBER
...........................................................................................................
15 INJECTORS
.............................................................................................................................
16 P ROPELLANTS
........................................................................................................................
17 ROCKET ENGINE
DESIGN.....................................................................................................
20
CONSTRUCTION....................................................................................................................
25 T HRUST
CHAMBER...................................................................................................................
25 INJECTORS
.............................................................................................................................
26 INJECTOR COVER
.....................................................................................................................
28 INJECTOR TUBE CONECTION
PIECE...............................................................................................
28 C OOLING JACKET
....................................................................................................................
29 C OOLING JACKET TUBE FITTINGS
................................................................................................
30 C LOSING SUPPORTS
.................................................................................................................
30 S
EALS...................................................................................................................................
31 F UEL TANK
............................................................................................................................
32 GAS TANKS
............................................................................................................................
33 S UPPORTING STRUCTURE
..........................................................................................................
33 P
LUMBING.............................................................................................................................
34 IGNITOR
................................................................................................................................
37
ASSEMBLY..........................................................................................................................
38 EXPERIMENTAL PROCEDURE
..............................................................................................
44 OPERATING PROCEDURE
...........................................................................................................
44 T
HRUST.................................................................................................................................
45 C HAMBER
TEMPERATURE..........................................................................................................
49 P RESSURE
..............................................................................................................................
50 SUPPLIERS AND COSTS
.........................................................................................................
51 C OST
....................................................................................................................................
51 S UPPLIERS
.............................................................................................................................
52 CONCLUSIONS AND RECOMMENDATIONS
..........................................................................
54
BIBLIOGRAPHY.....................................................................................................................
55 ANNEX: BLUEPRINTS
............................................................................................................
56 6. IM-2006-II-01vi TABLE OF FIGURESFigure 1. Flow of the
project...............................................................................................8
Figure 2. Schematic of the combustion chamber and nozzle [3].
..............................15 Figure 3. Types of injection
systems
[3].........................................................................17
Figure 4. Performance of some liquid propellants [3].
.................................................18 Figure 5.
Variation of flame temperature with O/F ratio [3].
........................................18 Figure 6. Specific
impulse as a function of chamber pressure [3].
............................19 Figure 7. Nozzle parameter for
various chamber pressures [3].................................21
Figure 8. Inside of the thrust
chamber............................................................................25
Figure 9. Nozzle.
................................................................................................................26
Figure 10. Fuel inlet in injector
piece..............................................................................27
Figure 11. Injector
holes...................................................................................................27
Figure 12. Angle of injector
holes....................................................................................28
Figure 13. Inside of cooling
jacket...................................................................................29
Figure 14. Weld of injector
cover.....................................................................................31
Figure 15. Weld of cooling
jacket....................................................................................31
Figure 16. Dry seals.
.........................................................................................................32
Figure 17. Fuel
tank...........................................................................................................33
Figure 18. Support structure.
...........................................................................................34
Figure 19. L-shaped
fitting................................................................................................35
Figure 20. Engine support, feeding hoses and
valves.................................................35 Figure
21. Bottom part of tank with an L-shaped
fitting...............................................36 Figure 22.
Schematic of hydraulic system
[3]................................................................37
Figure 23. Schematic of ignition system
[3]...................................................................38
Figure 24. Coupling of
o-ring............................................................................................38
Figure 25. Coupling of small dry
seal.............................................................................39
Figure 26. Assembly of injector and injector
cover.......................................................39
Figure 27. Coupling of thrust chamber and cooling
jacket..........................................40 Figure 28.
Coupling of 35 mm-hole dry
seal..................................................................40
Figure 29. Coupling of 30.2 mm-hole dry
seal..............................................................41
Figure 30. Coupling of injector assembly and thrust chamber
assembly. ................41 Figure 31. Coupling of
bolts.............................................................................................42
Figure 32. Coupling of engine with support
bar............................................................42
Figure 33. Coupling of tube
fittings.................................................................................43
Figure 34. Connection of hoses to
engine.....................................................................43
Figure 35. Schematic of thrust force in the support
bar...............................................45 Figure 36.
Schematic of signal conditioning circuit.
.....................................................47 7.
INTRODUCTION Rockets are nowadays a way of reaching high altitudes,
whether it is to deliver satellites to a low or high earth orbit,
meteorological devices to the upper atmosphere or other
experimental equipment.There are solid and liquid fuelrockets: the
solid fuel rockets were used in the early studies and the first
rockets built, but very quickly the liquid fuel rockets were
introduced, due to their ability to control the velocity and their
precision. However, because of their increased complexity, little
work has been done on them in Colombia, as said in [5]. The purpose
of this work, then, is to provide a basic practical work on liquid
fuel rocket engines, so that this becomes a first step in
developing liquid fuel rockets, parallel to the practical work on
solid fuel rockets that is being developed by [1], [2] and [5]. The
idea is also to demonstrate that the liquid fuel rocket engines can
also be built in Colombia, just like the solid ones, using
materials readily available to any civilian. The objectives of this
project are to search (and modify if necessary) an existing design
on a liquid fuel rocket engine, build this design with commonly
available materials and with a low cost (if possible), to test this
engine and to lay a background with the knowledge obtained on
liquid fuel rocket engines,for future reference. The advantage of
the liquid fuel rocket over the solid fuel rocket is that, since
the liquid fuel rocket has better control and more accuracy, and it
has a smoother acceleration (due to the greater mass of fuel that
it uses and of its components), it is preferred for the big
aerospace projects (including the manned missions). Since the
liquid fuel engine weighs up to 30% of the total empty weight, then
the idea is to load the rocket with the most fuel possible, and
this limits its acceleration. That is why the rocket ends up with a
smoother acceleration but a greater range, which is ideal to launch
precision instruments. Besides, the simplicity of a solid fuel
rocket is 8. IM-2006-II-018lost in the fuel, which is a complex
mixture with a special formulation and special burning conditions.
Also, since the pressure and acceleration are greater in a solid
fuel rocket, the casing must be thicker, thus increasing the empty
weight. [7] In this project, therefore, the basic equations for
developing the different parts of the engine will be presented and
used to validate an engine design, which will be built to show the
feasibility and performance. This process is illustrated in the
following figure.Figure 1. Flow of the project.The project is the
grey box that transforms the equations and parameters into an
engine that works according to the theory. The restrictions
associated with the finished product (the engine in this case) are
primarily ease of construction (including availability of materials
and costs), weight of the overall engine (which must be the
lightest possible) and portability (or selfstanding, meaning that
the overall construction is not restricted to work on a given area
but can be moved to any location with ease). Some other criteria
associated with this project is esthetics (overall aspect of the
finished product, which in this case is not so important), amount
to be produced (since this is not a finished product, it is not to
be mass produced yet; just one or maximum two units are to be
produced) and safety (it must be high). These elements are to be
given a relative value, according to their importance to the
project. 9. IM-2006-II-019Restriction / Criterion Relative value
Availability of
materials0.2Cost0.2Weight0.1Portability0.1Aesthetics0.05Production0.05Safety0.3The
highest criterion is safety, as always, because safety will allow
the repetition and reproduction of any results and procedures made
here. The next criteria are availability of materials and cost,
because one of the objectives of this project is to build a real
engine. The next criteria are weight and portability, which are
also important but not so much as the latter. If a lightweight and
portable engine is not found, then a heavier one will still work
(although it is not the preferred option). And the last two
criteria are aesthetics and production. It is not a requirement for
the engine to be beautiful, but it can not be very ugly, because
after all it must interest other people to continue working on it.
Production is not an important factor for now, because mass
production is not yet in sight, but eventually it will be. The best
solution is to build a rocket engine alone, not the whole rocket,
and its test stand. This way, the weight and portability are not
important. Also, the project becomes more accessible, because there
is no need to build the rocket body and launching equipment. 10.
PROPERTIES OF LIQUID PROPELLANTS [6] What is desired with the
liquid propellants is that they have a high chemical energy content
and that the combustion gases have a low molecular weight. Due to
this, the best fuel / oxidizer mixture is not the stoichiometric
one, but a mixture rich in fuel which generate low molecular weight
combustion products, such as H 2. Besides this, the addition of
metallic particles in suspension (such as beryllium or aluminum)
increases the specific impulse between 9 and 18%. However, these
particles can be toxic. Based on the information above, different
experimental analyses have determined that the best fuel and
oxidizer mixture is hydrogen and liquid fluorine respectively, with
beryllium particles in suspension. The specific impulse is 480
seconds with a chamber pressure of 1000 psi at sea level, and 565
seconds in vacuum, with an expansion ratio of 50 (relation between
the exhaust area and the throat area).Physical properties The
desired physical properties in liquid propellants are the
following: Low freezing point: Desired property for operation at
low temperatures, such as in space.High specific gravity: Is
desired because it will allow the propellant to be stored in a
reduced space, reducing the total weight of the vehicle and
improving its aerodynamics.Stability: It is convenient that the
propellant does not decay or decompose while it is in the storage
tank or in the feeding pipes.Heat transfer properties: It is
desired to have a high specific heat, high thermal conductivity and
high boiling point, when they are used to cool the nozzle and
combustion chamber.Pumping properties: A low vapor pressure is
desired to reduce the risk of cavitation in the turbomachinery (in
case the propulsion system uses 11. IM-2006-II-0111turbomachinery).
Besides, the propellant should have low viscosity so that the
system calibration is easier. Temperature variation: The physical
properties should vary little with temperature variations, so that
the calibration obtained is more precise.The properties should not
vary from time to time or between manufacturers. This is why the
propellant components and properties should be fully specified, so
as to guarantee uniformity in the properties. If these properties
are to change, additives can be added to the propellant.Combustion
properties All propellants should start the combustion process
readily to reduce the risks of explosion and to make it more
stable. Some propellants can start combustion when they come in
contact with each other. These are known as hypergolic propellants.
The use of these type of propellants greatly simplifies the
combustion process, because it eliminates the need for an ignition
system. If the propellants are not hypergolic they must be able to
start the combustion with a low energy level, so a low power
ignition system will suffice. Smoke should not appear in the
combustion products.Start And Ignition [6] Initially the propellant
flow is less than the operation flow and the mixture is different
than that during the operation. This period is known as the
preliminary stage. The low flow prevents the accumulation of
unburned propellant inside the combustion chamber, which can cause
an explosion. The flow should not be the full operational flow
until the combustion has not been completely initialized. The
chamber conditions in this preliminary stage include a low
injection velocity, the vaporization, atomization and mixture of
the propellants is incomplete. The 12. IM-2006-II-0112equivalence
ratios close to the stoichiometric deliver a high heat generation
ratio and allow the chamber to reach to the operating conditions
faster. The start time for combustion in the chamber is affected by
the following parameters: The time required to open the valves. It
can go from 0.002 to 1 second depending on the valve type. The time
required for the propellant to fill all cavities, pipes and
injectors. The time needed to form jets of propellant and its
atomization and mixture. The time required for the droplets to
evaporate and burn. This time is between 0.02 and 0.05 seconds.
Once there is combustion in a particular place, it takes certain
amount of time for the flame to propagate and raise the chamber
temperature. The time needed to raise the pressure to a point where
combustion can be self sustained and then to the operating point.
The start time increases with an increase in engine size. Small
engines usually require several milliseconds, while bigger engines
might require 1 second or more. For a more reliable start, one of
the propellants must arrive before the other to the combustion
chamber. For example, if a rich mixture is desired to start the
engine, the fuel must be injected first, and then the oxidizer. 13.
DESIGN EQUATIONS The momentum equation is mass times velocity. The
change of momentum is the one that produces force. P = M V dP dm dv
= V +M =F dt dt dt The first term in this equation corresponds to
the change of momentum of the escape gases coming out of the
nozzle. The second term corresponds to the force that the gases
make in the exit area of the nozzle. The equation can be rewritten
like this: & F = mV + ( pe pa ) Ae [1] The thust (pushing
force) is related to the pressure of the exhaust gases coming out
of the nozzle and the atmospheric pressure, since this net pressure
applied in the exhaust area of the nozzle adds to the overall
thrust. Maximizing this expression shows that the maximum thrust is
achieved when the gases are expanded to match the atmospheric
pressure. An equivalent exhaust velocity can be thus defined like
this: p pa & u eq = u e + e Ae , so that the effective thrust
is: F = m ueq .[1] & m To characterize the rocket engines, the
most important parameter is the specific impulse. The impulse is
the area under the curve of Thrust vs. time; it is the total
momentum transferred to the vehicle by the engine. It is a force
multiplied by a time (I = F * t = M * ueq ). The impulse per unit
mass flow would be equivalent to ueq or toF . The specific impulse
is: m &I sp =u eq .[1] g 14. 14IM-2006-II-01This value is
equivalent to the thrust generated by unit mass flow of fuel. In
any system of units this value is measured in seconds. It is also
expressed by the following expression: I sp =F [5]. mg &The
greater the specific impulse of the engine, the greater is
efficiency in producing thrust. Since the specific impulse depends
directly of the exhaust velocity of the gases, the less their
molecular weight, the greater the specific impulse will
be.[7]Nozzle For the operation of the nozzle, the flow must be
assumed as isentropic, compressible and unidimensional. Therefore,
the following relations between the properties of the gas and the
stagnation properties can be obtained:[1] To 1 2 =1 + M T 2 p o 1 2
1 = 1+ M p 2 1 o 1 2 1 = 1+ M 2 A 1 1 2 = 2 + 1 2 + { 1}M A* M [ +1
2 ( 1 ) ]The stagnation properties (To, po and o) are the ones that
are present in the combustion chamber, since the speed of the gases
is very small and can be neglected. The other properties (T, p and
) are present where a given Mach number is present. When the Mach
number is one, the properties are those of the throat (T*, p* and
*). The same happens for the throat and exhaust areas. The nozzle
has a convergent divergent geometry, because when the flow is
subsonic the flow accelerates by reducing the area; when the flow
is supersonic it is accelerated by increasing the area. The
narrowest section, called the throat, is 15. 15IM-2006-II-01where
the flow has sonic velocity (Mach = 1). The following graph shows a
schematic nozzle and combustion chamber.[3]Figure 2. Schematic of
the combustion chamber and nozzle [3].The throat area (A*) can be
determined by the following equation:[3] At =m RT * & p* gwhere
m is the mass flow, p* is the pressure at the throat, T* is the
temperature at the throat, R is the gas constant (R = Ru/Mw,
Mw=molecular weight of the gas), is the specific heat ratio and g
is the acceleration of gravity.Combustion chamber The defining
parameter of the combustion chamber is the characteristic length
(L*), which is defined as:[3] L* =Vc Atwhere Vc is the volume of
the combustion chamber and At is the area of the throat. The
combustion chamber cross-sectional area (Ac) should be at least
three times the nozzle throat area, so that the chamber is big
enough compared to the throat, and so the flow velocity in the
chamber is low. The volume of the chamber is given by: 16.
IM-2006-II-0116Vc = Ac Lc + convergent volume where the convergent
volume is the convergent part of the nozzle. For small nozzles, it
can be reduced to: Vc = 1.1 Ac Lc considering that the convergent
volume of the nozzle is about 1/10 of the chamber volume. The
chamber diameter should be, therefore, three to five times the
diameter of the throat.[3] The combustion chamber thickness should
be calculated to withstand the stresses generated by the pressure
inside. The expression used is:=pD 2t wwhere is the stress applied
to the chamber material, p is the inside pressure, D is the chamber
diameter and tw is the wall thickness. The stress applied must be
way less than the resistance of the material used to make the
combustion chamber, to take into consideration defects of the
material and stress concentrations.[3]Injectors The injectors are
in charge of introducing the fuel and oxidizer into the combustion
chamber in a liquid fuel rocket engine. They must atomize the
propellants and make sure that the fuel and oxidizer mix thoroughly
in the combustion chamber. One type of injector is the impinging
stream, which is a hole through which the propellants are
introduced into the combustion chamber. The other type is the spray
nozzle, which is originally design for home oil burners. The
following figure shows both types of injectors.[3] 17.
17IM-2006-II-01Figure 3. Types of inj ection systems [3].The mass
flow of propellant can be determined by the following
expression:[3] & m = C d A 2 g p where Cd is the orifice
discharge coefficient (typically between 0.5 and 0.7), A is the
area of the orifice, g is the acceleration of gravity, is the
density of the propellant and p is the pressure drop across the
orifice. The injection velocity is given by the expression: v = Cd
2gpPropellants There are several combinations of fuels and
oxidizers that can be used in a liquid fuel rocket engine. However,
[3] recommends the use of gaseous oxygen and a hydrocarbon fuel as
the best combination; it is readily available, reasonably safe,
easy to handle and inexpensive. The following table lists some
liquid propellants. 18. 18IM-2006-II-01Figure 4. Performance of
some liquid propellants [3].The mixture ratio is defined as the
flow of oxygen divided by the flow of fuel (O/F). The highest
temperature is achieved at the stoichiometric ratio of oxygen to
fuel, as it is shown in the following graph at 300 psi chamber
pressure.[3]Figure 5. Variation of flame temperature with O/F ratio
[3]. 19. 19IM-2006-II-01Because of this, it is recommended that the
mixture be a little rich, so that the flame temperature is as low
as possible without losing performance. The following graph relates
the chamber pressure to the specific impulse for two different
propellants.[3]Figure 6. Specific impulse as a function of chamber
pressure [3].With the help of this graph the specific impulse can
be determined, by defining the chamber pressure and the type of
propellant to be used. Knowing this and the required thrust for the
desired engine lead to determine the total propellant flow required
for the desired operation. The fuel and oxidizer flow can also be
determined.[3] m= &F I sp gr r +1 & m & mf = r +1 &
= mo + m f & & m & & mo = mWhere m is the total
mass flow, m o is the oxidizer mass flow, m f is the fuel mass flow
and r is the oxygen-fuel ratio. 20. ROCKET ENGINE DESIGN [3]The
proposed design for a rocket engine has a combustion chamber
pressure of 300 psi (2068 kPa) and a thrust of 20 pounds (9.07 kg =
88.9 N), using gaseous oxygen and gasoline. It is assumed that the
exhaust gases have a specific heat ratio (k) of 1.2. From figure 6
the specific impulse and oxygen to fuel ratio can be determined.
The specific impulse for this case is about 260 seconds, and the
O/F ratio is 2.5. Therefore, the mass flow rate is: m= &20 F =
= 0.077 lb / sec = 0.035 kg / s = 35 g / s I sp 260The fuel and
oxygen flow rate are: & 0.077 m = = 0.022 lb / sec = 10 g / s O
/F +1 3.5 m(O / F ) 0.077 * 3.5 & & mo = = = 0.055 lb / sec
= 25 g / s O /F +1 3.5 mf = &From [3] the chamber temperature
is 5742F (3172C), or 6202 R (3445 K). The temperature and pressure
at the nozzle are: T * = 0.909To = 0.909 * 6202 = 5650 R = 3132 K
p* = 0.564 Po = 0.564 * 300 = 169 psi = 1165 kPa The nozzle throat
area and diameter can now be determined. (Ru=1545.32 ft lb/(lb 2
R), Mm=24, R=65 ft lb/(lb R), gc=32.2 ft/s .A* = d* =m RT * 0.077
65 * 5650 & = = 0.0444 in 2 = 0.286 cm 2 p * kg c 169 1.2 *
32.2 4A *=4 * 0.0444= 0.238 in = 0.605 cm 21. IM-2006-II-0121From
the following table the exhaust velocity, area (therefore diameter
too) and temperature can be determined [3].Figure 7. Nozzle
parameter for various chamber pressures [3].ve = M e Ce = M e kRTe
Tc = 2.55 1.2 * 65 * 0.606 * 6202 = 7835 ft / s = 2376 m / s TcAe
A* = 3.65 * 0.0444 = 0.162 in 2 = 1.045 cm 2 A* 4 Ae 4 * 0.162 de =
= = 0.4542 in = 1.154 cm Ae =Te =Te T * = 0.606 * 6202 = 3758 R =
2088 K T*For the combustion chamber, L*=60 in (152.4 cm) is used.
Therefore, the chamber volume is: Vc = L * A* = 60 * 0.0444 = 2.67
in 3 = 43.75 cm 3 It is also assumed that the chamber diameter dc
is 5 times that of the throat. Now the chamber length can be
determined. d c = 5d * = 5 * 0.238 = 1.19 in = 3.02 cm Ac = 4d c =
1.11 in 2 = 7.16 cm 2 2Vc = 1.1Ac Lc Lc =Vc 2.67 = = 2.18 in = 5.54
cm 1.1Ac 1.1 *1.11 22. IM-2006-II-0122The combustion chamber and
nozzle will be made of copper. The thickness of the wall can be
calculated as follows, knowing the pressure and diameter of the
chamber, and assuming a resistance of copper () of 8000 psi (55.14
MPa).=pd pd 300 * 1.19 t= = = 0.0223 in = 0.0566 cm 2t 2 2 *
8000However, for safety factors, the thickness will be set at 3/32,
or 0.09375 in (0.24 cm). The average heat transfer from inside the
combustion and chamber and nozzle 2 2 can be assumed to be 3
Btu/(in sec) (490.58 W/cm ), through the outer surfacearea of the
chamber and nozzle. The area is calculated as follows: A = (d c +
2t )Lc + area of nozzle cone The area of the nozzle cone can be
estimated as 10% of the total area. Therefore, A = 1.1 (d c + 2t
)Lc = 1.1 (1.19 + 2 * 0.09375) * 2.18 = 10.37 in 2 = 66.90 cm 2 The
total heat transfer out of the combustion chamber and nozzle is:
& & Q = qA = 3 *10.37 = 31 Btu / sec = 32.705 kWRe = Pr =4m
& 4 * 0.035 = D * 0.0302 * cphg = 0.026 Re 0.8 Pr 0.4 DTo cool
the engine with water, a temperature increase of 40 F (4.44C) is
going to be used. The required flow of water can be calculated:
& & & Q = mC p T m =& Q 31 = = 0.775 lb / s = 0.352
kg / s C p T 1* 40The velocity of the water is set to be 30 ft/s,
so the annular flow passage must be calculated as follows. 23.
IM-2006-II-0123& m = Av A=(d d1 4 2 d1 = d c + 2t d2 =22)4m 4 *
0.775 & + d 12 = + (1.19 + 2 * 0.09375 )2 = 1.475 in = 3.747 cm
v * 62 * 30That makes the water flow gap to be (d2-d1)/2=0.0425 in
(0.108 cm). Hydraulic diameter:([4 * Area 4 * 0.25 Lc d 1 + d 2 =
Dh = Wet perimeter Lc [d1 + d 2 ] =22]) = d+ d2 2 d1 + d 2 211.3775
2 + 1.475 2 = 1.428 in = 3.63 cm 1.3775 + 1.475& 4m 4 * 0.352 =
= 12346 D * 0.0363 * 0.001 c p 0.001 * 4.182 = = 0.00747 Pr = k
0.56 Re =hl = 0.023 c pm 0 .2 2 3 0.352 & 2 Re Pr = 0.023 *
4.182 * *12346 0 .2 * 0.00747 3 A 0.25 1.475 2 1.3775 2()=
0.6163The fuel injector is going to be a commercial spray nozzle
with a 75 spray angle, preferably made of brass. The capacity of
the spray nozzle is determined by the fuel flow rate: & m =
0.022 lb / s = 1.32 lb / min = 0.22 gal / min If an impringing jet
injector had been used, the hole area would be calculated as 3
follows, assuming a Cd of 0.7, a density of gasoline of 44.5 lb/ft
and a pressuredrop of 100 psi. 24. IM-2006-II-01A=mf & C d 2 g
p24 0.022== 0.000706 in 2 = 0.00455 cm 20.7 2 * 32.2 * 44.5 *100If
one hole is used, its diameter would be of 0.030 in (0.0762 cm)
(use a number 69 drill); if two holes are used, their diameter
would be 0.021 in (0.05334 cm) (number 75 drill). For the oxygen
injector, a velocity of about 200 ft/s (60.96 m/s) is desired (not
higher, because it is not desirable for the oxygen to reach sonic
velocity). Assuming a pressure drop of 100 psi (689.29 kPa), the
pressure before the oxygen enters the injector is 400 psi (2757.14
kPa) (adding the chamber pressure). From [3] the oxygen density can
be determined (at 68F [20C]). 2 = 1 p 2 p = 2.26 3 = 36.27 3 1 ft m
lbA=kgm 0.055 & = = 0.0175 in 2 = 0.1129 cm 2 v 2.26 * 200This
is the area required for the oxygen injection, assuming
incompressibility for the gas flow. If 4 holes are used, then each
one has a diameter of 0.0747 in (0.19 cm) (number 48 drill). The
fuel and oxygen jets should be at an angle of 45 with respect to
the injector face and intersecting at about inch (0.635 cm) from
it. 25. CONSTRUCTION The actual construction of the rocket engine
required several things to be slightly different than what was
designed, to adjust to the available tools and supplies. All hole
shaft assemblies were machined to a tolerance of H7n6, a transition
fitting to provide a tight fitting but allow for easy
assembly.Thrust chamber The thrust chamber has the combustion
chamber and the nozzle in one piece, for ease of construction. The
piece was made from solid bronze, because it is easier to machine
than copper and still has similar mechanical properties, desirable
for the piece. The starting blank was a bronze cylinder of 1 (44.45
mm) diameter and 4 long (100 mm). After the front was faced, the
outside was machined to a diameter of 35 mm. A 5.5 mm hole was
drilled through the blank. Then, successive holes were drilled with
and 1 to a depth of 60.4 mm (not counting the cone of the drill
bit). Then the inside was machined to achieve an inner diameter of
30.2 mm.Figure 8. Inside of the thrust chamberTo machine the other
side of the blank, a 30.2 mm cylinder was previously machined to
fit inside the hole, so that the blank could be tightened without
deforming the piece. A drill bit was sharpened to a half angle of
about 15, to machine the inside of the nozzle. With the blank in
place, the front was faced to 26. IM-2006-II-0126make the piece
have a length of 75.22 mm. Then this drill bit was used to drill a
cone, to a depth of 7 mm, then advancing until the larger diameter
of the cone was 11.54 mm. For the outside of the nozzle, just the
13 mm diameter dent was machined to a depth of 2.4 mm. The outside
cone was not machined to leave more material to use as a heat sink
and for ease of manufacture, because the weight was not an
important issue.Figure 9. Nozzle.Injectors The injector block (or
combustion chamber lid, as it is named in the blueprints) was also
machined from a cylindrical blank of 1 (44.45 mm). The propellant
manifold part was machined first. This is the part where the
propellants come from the hoses and then goes to the injectors.
After facing the blank, the entire cylinder was machined to an
external diameter of 44 mm. Then material was removed to produce a
cylinder of outer diameter and a length of 30 mm. A hole of 12 mm
and 30 mm depth (including the drill bit cone) was made. These
dimensions allowed for the tube fitting to be screwed and thicker
walls to be used (3.5 mm instead of 3 mm as shown in the
blueprint). This change was made also because the tube fitting had
a diameter of , so the 10 mm hole initially planned did not work.
Finally, a 3 mm wide channel was dug on the outer surface of the
cylinder to a depth of 1.5 mm, to allow an o-ring to be placed. 27.
IM-2006-II-0127Figure 10. Fuel inlet in inj ector piece.The other
side was machined and faced to produce a piece of 37 mm in length.
Then a 30.2 mm cylinder was machined to a depth of 5.5 mm. This
part would fit inside the combustion chamber, so a tight fit had to
be assured. All the flat surfaces had to be given a flat finished,
as shown on the blueprints. These faces would come in contact with
other surfaces to seal the engine, so a good surface finish is in
order. Because of the small thickness of the outer ring, no channel
was dug for an o-ring.Figure 11. Injector holes.The fuel injection
hole was drilled with a 0.7 mm drill bit, using a mototool. It was
drilled through the center of the injector face. For the oxygen
injection holes, a 1.9 mm bit was used. However, these holes were
drilled at an angle with respect to the fuel injection hole, to
produce am impringing jet injector. The piece was held tight in the
drill stand, which was tilted at an angle of approximately 30
relative to the fuel injection hole, so the drilled holes were at
the mentioned angle. 28. IM-2006-II-0128Figure 12. Angle of
injector holes.Injector cover Or oxygen chamber cover, as it
appears on the blueprints. This piece started also with a 1 solid
cylindrical blank. First it was faced and then machined to a
diameter of 44 mm. Then it was machined to a diameter of 40 mm for
a length of 28.5 mm, making sure the resulting tab was
perpendicular. After this, a hole was drilled through the center of
the blank. The other side was faced and cut to make the whole piece
have a length of 30 mm. Then a 1 hole was drilled to a depth of 25
mm (including the drill bit cone tip). After this, the inside was
machined to produce an internal diameter of 30 mm and a wall
thickness of 5 mm in all faces. No o-ring channel was made because
the thickness of the piece did not allow for a channel. On the
side, a hole was drilled, as shown in the blueprints, for the
incoming line of oxygen. The a xis of the hole intersects with the
axis of the piece. Using a drill bit, a hole 2.5 mm deep was
drilled, to make a guide for the injector tube fitting.Injector
tube conection piece Or oxygen connection piece, as it appears in
the blueprints. This piece was made from a (19.2 mm) solid
cylinder. After it was faced, the outside was machined to a
diameter of 19 mm and the inside was drilled with a 12 mm drill
bit. It was then cut to a length of 10 mm. The curve to fit the
piece to the cooling jacket was made using the milling machine with
a bit of around 40 mm in diameter. 29. IM-2006-II-0129This piece
was soldered to the injector cover, over the hole on one side. A
silver weld was used to create a fillet around the piece. Then, the
inside cylinder was threaded to fit the NPT fittings.Cooling jacket
Or water jacket piece, as seen in the blueprints. The cooling
jacket was made from a solid cylinder of 1 (44.45 mm) diameter and
100 mm length. First it was faced and machined to an external
diameter of 42.27 mm. Then a 13 mm hole was drilled through the
center. The other side was cut and faced to make the length of the
whole piece 73.82 mm. Then successive holes were drilled, using , 1
and 1 drill bits, to a depth of 70 mm (counting the bit cone). Then
the inside was machined to achieve an internal diameter of 37 mm
and allow for a wall thickness of 2.4 mm at the flat face. Then,
holes were drilled through the side surface, as shown in the
blueprints. However, the holes were slightly off-center to produce
swirling in the incoming cooling water.Figure 13. Inside of cooling
j acket.This piece could be made from a tube blank to avoid wasting
most of the material. However, for this project it was less costly
to use a solid blank, because the shortest tube sold was 1 m in
length. Therefore, to build only one engine it is 30.
IM-2006-II-0130cheaper to buy the solid blank, but to build several
engines it is useful to buy the tube.Cooling jacket tube fittings
Or water connection piece, as seen in the blueprints. These pieces
were made from a (19.2 mm) solid cylinder. After it was faced, the
outside was machined to a diameter of 19 mm and the inside was
drilled with a 12 mm drill bit. It was then cut to a length of 10
mm. The curve to fit the piece to the cooling jacket was made using
the milling machine with a bit of around 40 mm in diameter. This
curve was milled eccentrically to allow fit with the holes of the
cooling jacket and allow the cooling water to swirl inside.Closing
supports The round closing supports were made from a bronze plate 3
(76.2 mm) wide and (6.35 mm) thick. Two square plates were cut from
this bronze plate. Successive holes were drilled through the
center, using , and 1 drill bits. Using this hole, the square
plates were machined to become round using the turning machine. For
the combustion chamber cover round support, the inner hole was
machined to a diameter of 40 mm. Then a 44 mm diameter cylinder was
machined to a depth of 3 mm. For the water jacket round support the
inner hole was made 35 mm in diameter. Then, a 42.27 mm diameter
hole was machined to a depth of 2.6 mm. In both supports 4 holes of
diameter were drilled in a 66.14 mm diameter circle, as shown in
the blueprints. These holes had to be made a little bit bigger
(5/8) in order to allow the bolts to pass freely. The combustion
chamber cover closing support was welded to the injector cover, as
shown in the blueprints, using a silver weld. 31.
IM-2006-II-0131Figure 14. Weld of injector cov er.The water jacket
closing support was welded to the cooling jacket using too the
silver weld.Figure 15. Weld of cooling j acket.Seals One o-ring
(15mm diameter x 2 mm thickness) was used in the fuel manifold,
where the channel was dug. The o-ring had to be stretched in order
to achieve the required thickness for a tight fit and easy
assembly. For the other joints, rings of asbestos dry seal were
used, to be able to resist high temperatures. One dry seal was
placed between the injector and the injector cover. This seal had
an internal diameter of 30 mm and external diameter of 44 mm. 32.
IM-2006-II-0132And 2 dry seals were used between the injector
assembly and the water jacket assembly. Both seals had an external
diameter of 76 mm; one had an internal diameter of 35 mm and the
other one an internal diameter of 30.2 mm. Both of these seals had
4 holes of each, placed in a circle 66.14 mm in diameter and with
the same arrangements as the closing supports.Figure 16. Dry
seals.Fuel tank The fuel tank was made using a sch.80 petroleum
tube, of 4 inches of diameter and 300 mm long. The tube had to be
cleaned near the ends and a chamfer had to be cut to allow for
welding. The lids cut from a steel plate thick were 4 in diameter
and had 2 holes of 12 mm in diameter. The holes were threaded to
screw the NPT tube fittings. These lids were also cleaned to allow
for welding. The lids were welded to the tube using a 7013
electrode. 33. IM-2006-II-0133Figure 17. Fuel tank.Gas tanks One
oxygen tank and one nitrogen tank were needed for the assembly.
These tanks had to supply a pressure of at least 400 psi in order
to reach the desired thrust. The first choice was to use commercial
tanks with high pressure regulators. These tanks have gas stored at
a pressure of about 1500 psi and have a capacity 3 of about 6 m .
Therefore they could provide a steady 400 psi flow. However,
thehigh cost of the pressure regulator did not allow this option to
be used. Therefore, the other choice was to use small 3 L tanks
with the oxygen and nitrogen at about 500 psi. The flow would not
have a steady pressure, it would decrease monotonically. However,
for a few seconds (around 4) the average pressure would be 400 psi.
This set up would only allow one testing for a few seconds, while
the tanks empty, but it is a viable possibility.Supporting
structure The supporting structure was made of steel angles (5 mm x
5 mm). The support structure was built as a prism, with a square
base of length 750 mm and a height of 1500 mm. In the middle, other
steel angles were placed to support the fuel tank and the engine. 4
long angles (1000 mm), 13 short angles (750 mm), 2 shorter angles
(500 mm) and smaller pieces (diagonal supports) were used. These
angles were joined by screws. 34. IM-2006-II-0134For the engine
support, a cantilever bar was used. It was cut from an A-36
structural steel plate. Then, the hole-array was drilled to allow
the engine to be attached and the holes to hold the bar to the
supporting structure.Figure 18. Support structure.Plumbing The
hoses used for the gas lines were stainless braided Teflon. 3 hose
pieces were needed: one 1000 mm piece and two 500 mm pieces. The
hoses used for the fuel lines were two SAE 100 rated for 190 bar,
with a length of 500 mm each. All hoses were fitted with NPT female
threads. The hoses used for the water cooling were 3/8 diameter
plastic hoses. The valves used were two stainless steel valves,
rated for use with natural gas and up to 1000 psi. 35.
IM-2006-II-0135The fittings used were NPT male threaded. There were
6 straight fittings and 3 L-shaped fittings. There were also 2 hose
fittings, to connect the water hoses, and 2 lids to close the
filling hole and the drain hole in the fuel tank.Figure 19.
L-shaped fitting.For the oxygen line, two straight fittings were
screwed to each end of the valve. The 1000 mm stainless braided
Teflon hose was screwed to one fitting at one side of the valve,
and one of the 500 mm Teflon hoses was screwed to the other side.
For the nitrogen line, one 500 mm Teflon hose was screwed to a
straight fitting, which in turn was screwed to the top of the fuel
tank. For the fuel line, one of the SAE 100 hoses was screwed to an
L-shaped fitting, which in turn was screwed to the bottom of the
tank. The other valve was connected with straight fittings on both
sides. The hose that was connected to the fuel tank was connected
to one side of the valve, and the other SAE 100 hose was connected
to the other side of the valve.Figure 20. Engine support, feeding
hoses and v alves. 36. IM-2006-II-0136Figure 21. Bottom part of
tank w ith an L-shaped fitting.The original design [3] required a
nitrogen purge line, which is a line that carries nitrogen directly
into the engine to clean it of residual fuel after a burn has been
made. However, this purge line required a check valve to a void
fuel from entering this line. A check valve with the required
resistance (about 500 psi) could not be found, so in this project
no purge line was used. 37. IM-2006-II-0137Figure 22. Schematic of
hydraulic system [3].Ignitor The ignition system for the rocket
engine was made using wire and cotton. Two wires were pealed and
left with a small gap (1/8). A piece of cotton is put around the
wire where the gap is. When the engine is going to be started, the
cotton is soaked in fuel and electricity is allowed to pass through
the wires. A spark is created and it ignites the cotton. However,
there should be oxygen passing through the cotton for the ignition
to be effective. 38. IM-2006-II-0138Figure 23. Schematic of
ignition system [3].ASSEMBLY The rocket engine assembly procedure
was as follows: 1. The structural assembly was joined, as the
figure shows. The fuel tank was placed and the cantilever bar was
screwed to the assembly. 2. The o-ring was placed in the cavity of
the injector piece.Figure 24. Coupling of o-ring. 39.
IM-2006-II-01393. With the injector cover upside down, the small
dry seal was placed in the center cavity.Figure 25. Coupling of
small dry seal.4. The injector piece was inserted in the injector
cover. The side with the o-ring was inserted first, until the
surface of the injector is in contact with the dry seal.Figure 26.
Assembly of injector and inj ector cover.5. The thrust chamber was
inserted in the cooling jacket assembly (previously welded with the
closing support). 40. IM-2006-II-0140Figure 27. Coupling of thrust
chamber and cooling jacket.6. The dry seal with the inner 35 mm
hole was placed on the top of the injector assembly (with the
assembly still upside down).Figure 28. Coupling of 35 mm-hole dry
seal.7. The dry seal with the inner 30.2 mm hole was placed on top
of the cooling assembly (with the thrust chamber inside). 41.
IM-2006-II-0141Figure 29. Coupling of 30.2 mm-hole dry seal.8. The
injector assembly was placed on top of the cooling assembly,
covering the thrust chamber with the injector face and matching the
holes for the bolts.Figure 30. Coupling of inj ector assembly and
thrust chamber assembly.9. Four bolts were inserted through the
holes, from the bottom side. 42. IM-2006-II-0142Figure 31. Coupling
of bolts.10. The bolts (with the whole assembly) were inserted
through the holes in the cantilever bar and secured with
nuts.Figure 32. Coupling of engine w ith support bar.11. The hose
fittings were screwed to the cooling jacket connection tubes, one
L-shaped fitting was screwed to the top of the injector assembly
and one straight fitting and another L-shaped fitting were screwed
to the side of the injector assembly. 43. IM-2006-II-0143Figure 33.
Coupling of tube fittings.12. The oxygen hose was screwed to the
connection on the side of the injector assembly, the fuel hose was
screwed to the fitting on top of the injector and the water hose
was connected to the hose fitting.Figure 34. Connection of hoses to
engine. 44. EXPERIMENTAL PROCEDURE First, a leak test should be
performed to check all joints. For the fuel line and cooling water
line, water can be used to pressurize the line and check for leaks.
If there are leaks in the joints, they must be tightened or Teflon
tape must be put to the thread prior to screwing. For the oxygen
line, compressed air can be used to pressurize the line.Operating
procedure When the leak test is finish, the engine can be started.
The procedure to start the rocket engine is as follows [3]: 1. The
test area must be clear and all personnel secured. A fire
extinguisher must be located in the test area where it can be
easily reached. 3 2. The fuel is poured in the fuel tank. No more
than 56 cm of fuel should be inthe fuel tank, to limit the time of
operation of the engine to 4 seconds. 3. The ignitor is soaked in
fuel and placed inside the combustion chamber and be secured. 4.
The cooling water is allowed to flow through the engine. 5. The
oxygen line is opened a little bit. 6. The ignitor is energized. At
this point there should be sparks coming out of the engine. 7. The
fuel line is opened a little bit. Now there should be flames coming
out of the engine and a low whistling sound. 8. Both oxygen and
fuel lines must be rapidly opened completely to avoid combustion
instabilities. The noise produced is loud, but it is an indication
of good operation. 9. The exhaust should be transparent but the
mach diamonds visible, indicating that the mixture is
stoichiometric. However, if the exhaust is bright yellow, it means
that the mixture is rich. Therefore, the fuel line should be 45.
45IM-2006-II-01closed a little bit. If the e xhaust is bluish, it
means that the mixture is poor. The oxygen line should be closed a
little bit. 10. The engine should be allowed to run until the fuel
runs out. That way, the gaseous nitrogen purges the fuel line, and
then the oxygen can be shut down (should there still be oxygen).
11. If the engine has to be shut down before it runs out of fuel,
then the fuel line must be shut down first, then the oxygen line.
12. The cooling water should be left on for a couple of minutes to
assure the engine is effectively cooled down. If a new test wants
to be run, a new ignitor is needed. The tanks should be filled
again and the lines and engine inspected for leaks and possible
damage. If any piece shows any sign of damage it must be replaced
with a new one. Now that the operating procedure for the rocket
engine has been established, the measuring of the thrust can be
made.Thrust To measure the thrust of the rocket engine an extension
gauge is used in a long bar [8]. The rocket engine on one side
pushes the bar with a force that produces deflection on it. The
gauge, on the other end of the bar, measures this deflection. The
thrust force, then, can be inferred.Figure 35. Schematic of thrust
force in the support bar.=Mc 6 M = 2 (For a rectangular cross
section). I bh 46. 46IM-2006-II-01 = E The change in length of the
gauge is proportional to a resistance change, which is in turn
measured with a Wheatstone bridge. The gauge takesthe place of
oneresistance. Knowing the values of the resistances of the gauges,
their deflection can be calculated, knowing the gage factor. This
factor relates the change in resistance with the deflection and the
nominal resistance of the gauge. R = f R The voltage between the
two nodes of the Wheatstone Bridge is calculated by the formula: R2
R4 V = V , where R1 is the gauge, and is represented as R+R. If R1
+ R 2 R 3 + R 4 all the resistances are the same, this expression
can be rewritten as : V =V R . 4RThe gauge to be used is a Vishay
Micro-Measurements Student Gauge (CEA-06240UZ-120), that has a
nominal resistance of 120.0 +/- 0.3% and a gage factor of 2.075 +/-
0.5%. The thrust force measured can be represented by the following
equation, which is a combination of the equations shown before:
F=bh 2 E 4V 4 1 2 2 1 1 = b h L f V 6L f 6The propagation of error
can be determined by the following equation [8]: 47.
47IM-2006-II-01UF U U U U = b + 2 h + 2 L + f F L f b h 2222 U V +
V 2And the error of the V term is as follows: 22U V U U U = V + R +
R V V R R 2The following table shows the given values for the
different parameters and the expected values of Thrust force,
stress, strain, R and V. F (N) L (m) b (m) h (m) E (GPa) R (ohms) F
V (V) R2 (ohms) R3 (ohms) R4 (ohms)88 0,59 0,05 0,00635 200 120
2,075 12 120 120 120sigma (Mpa)154,514229deformation
(micro)772,5711451delta R (ohms) delta V (V)0,192370215
0,004805404The voltage obtained is then passed through a low pass
filter with a cutoff frequency of 5 Hz, to eliminate noise and
combustion instabilities that are not desirable for this measure.
It is amplified by a factor of 1000 (using 3 consecutive 10-fold
amplifiers), so the obtained expected voltage is 4.805 V. This
means that the voltage measured must be multiplied by a factor of
18.3127176, to obtain a value of 88 N, which is the expected
thrust.Figure 36. Schematic of signal conditioning circuit. 48.
48IM-2006-II-01The following table shows the values of the
uncertainties (errors) of each parameter and the resulting
uncertainty of the measurement. Uv UdeltaR UR0,05 0,00057711 0,36Ub
Uh UL Uf UdeltaV2,50E-05 2,50E-05 5,00E-04 1,04E-02 2,85754E-05UF
(%) UF1,12019629 0,985772735This shows that the thrust measured
will have an uncertainty of 1.12%. If the expected thrust is of 88
N, then the uncertainty will be of 0.985 N. This data is expected
to be taken by a data adquisition card, such as a 12-bit Labjack
card. The expected resolution can be obtained as follows [8]: V =V
, where V is the feeding voltage and n is the number of bits of the
card. If 2nthe card is powered with 12 V, then the resolution is of
0.00292 V. When multiplying this by the factor of 18.3127176, a
resolution of 0.0536 N is obtained. When taking this resolution and
the uncertainty, the overall uncertainty of the measurement is
obtained. U measurement = U F + Re s 2 = 0.987 2The overall
resolution of the adquisition system will therefore be 0.987 N. The
purpose of this work is to measure the thrust force. However, more
measurements can eventually be made. Such measurements include
chamber temperature and pressure. 49. 49IM-2006-II-01Chamber
temperature [9] Since this engine is water cooled, the increase in
the temperature of the water as it comes out of the engine
(Tout-Tin) can be used to infer the inner combustion chamber
temperature (Tc). The heat generated from the inside of the
combustion chamber is transferred through convection to the chamber
wall, then by conduction through it and then by convection to the
cooling water. The heat transferred to the water is determined by
the equation: & & Q = mC p (Tout Tin )This heat is
transferred through the hot gas and the water by convection and
through the thrust chamber wall by conduction. The following
equations illustrate this. & Q = h g A (Tc Twall ,gas ) & k
A Q = wall (Twall, gas Twall,liquid tw & Q = hl A(Twall,liquid
Tliquid )Convection)Conduction ConvectionTherefore, by knowing the
entrance and outlet temperatures of the cooling water, and by using
an average temperature for the liquid, the temperature of the wall
at the liquid side can be determined. With this temperature, the
temperature at the gas side of the wall can also be determined. And
with this, the temperature of the inside gas can be determined. The
convection coefficients can be calculated for both the liquid and
the gas, using the following correlations. For the gas convection
coefficient: 50. 50IM-2006-II-01Re = Pr =& 4m D cphg = 0.026 Re
0.8 Pr 0.4 DAnd for the liquid convection coefficient:hl = 0 .023 c
p& m 0. 2 2 3 Re Pr AThe following table shows calculations
made based on expected values. T in (K) Q dot (W) hl (W/m^2 K) hg
(W/m^2 K) m dot water (kg/ s) Cp water (J/kg K) ro (m) ri (m) A
liquid (m^2) A gas (m^2) k wall (W/mK) L (m)298 12000 9576,14
731,87 0,352T out (K) T liquid (K) T wall liquid (K) T wall gas
(K)306,1518195 302,0759097 489,0883049 502,2964239Tc
(K)3338,1776344182 0,0175 0,0151 0,0067007 0,00578175 385
0,0554Therefore, assuming that the temperature of the water at the
entrance of the cooling jacket is 298 K and the exit temperature is
306 K, the chamber temperature would be expected to be around 3300
K, which is a typical value for these engines.Pressure The
measuring of pressure involves placing manometers directly on the
areas of interest, such as the gas tanks, fuel tank, engine
manifold and combustion chamber. This last measure requires careful
design, because it involves modifying the combustion chamber and
altering the mechanical properties of the materials. For further
projects it is a good performance parameter. 51. SUPPLIERS AND
COSTS One of the purposes of this work is to provide an experience
and to leave knowledge for future projects, a list of suppliers and
the costs involved in making this engine will be shown.Cost The
following costs are in Colombian Pesos, and may vary with time.
Engine parts: 300 mm solid bronze bar, 1 diameter:$ 87,200100 mm
solid bronze bar, diameter:$ 5,400250 mm bronze plate, 3 x cross
section:$ 25,0001 O-ring, 15mm x 2mm:$ 1,0003 dry seals:$ 6,0004
UNC bolts and 4 nuts:$ 2,000Silver welding:$ 22,000TOTAL:$
148,600Hoses and valves: 2 stainless steel valves:$ 41,8002 m
stainless threaded Teflon hose:$ 67,1001 m SAE 100 hose (Hca R-1):$
10,8004 Capsules for R-1 hose:$ 11,2006 Capsules for Teflon hose:$
14,20010 Female fittings, NPT:$ 31,4003 L-shaped fittings, NPT:$
25,1006 straight fittings, NPT:$ 13,600TOTAL:$ 215,200 52.
IM-2006-II-0152Support structure: 15 m steel angle:$ 150,000600 mm
A-36 plate, thick:$ 11,000Screws and nuts:$ 4,000TOTAL:$
165,000Electronics: Protoboard:$ 13,000Resistances:$ 1,0001
Operational amplifier:$ 1,300Wire:$ 5,000TOTAL:$ 20,300Fuel and
Tanks: 300 mm Sch.80 tube:$ 25,0002 thick steel plates, 4
diameter:$ 15,000Oxygen tank:$ 75,000Nitrogen tank:$ 75,0001 gal of
Fuel:$ 7,000TOTAL:$ 197,000TOTAL COST:$ 746,200Suppliers The
following is the list of suppliers used in this project. Bronze
material: Distribronces Seco Ltda. Diagonal 15 # 22-28. Tel: 247
5644. Bogot D.C. 53. IM-2006-II-0153Promecol Ltda. Calle 13 #
21-63. Tel: 247 8320. Bogot D.C.Hoses, Valves, O-rings and
Fittings: Suministros Hidrulicos Ltda. Cra 25 # 15-09. Tel: 247
4252. E-mail: [email protected]. Bogot D.C.Cadenas y
Correas Ltda. Diagonal 15 # 25-66. Tel: 247 2988. E-mail:
[email protected]. Bogot D.C.Ferretera Sicar Ltda. Cra 25
# 15-36. Tel: 277 2088. Bogot D.C.Oxygen and Nitrogen: Hidroprob.
Cra 21 # 65-38. Tel: 255 1529. Bogot D.C.Silver Welding: Metal
moderno, Soldaduras especiales. Cra 17 # 19-24. Tel: 480 6377.
Bogot D.C.Dry seals: El palacio del empaque. Cra 14 # 4-79. Tel:
246 5756.Tubes and plates for tanks: Hierros y Maquinaria La 14
Ltda. Calle 14 # 20-60. Tel: 237 1045. E-mail:
[email protected]. Bogot D.C.Steel plates: Cortametales Ltda.
Cra 25 # 17A-57. Tel: 360 0836. Bogot D.C. 54. CONCLUSIONS AND
RECOMMENDATIONS This project was made up until the construction of
the engine and support structure. Although the testing could not be
done, an important part of the objectives was reached. The rocket
engine made proves that a liquid fuel rocket engine can be made in
Colombia with materials readily available to any person interested
in doing so. This is one step taken away from the amateur level and
one step taken towards a more serious approach to the liquid
rocketry area. The support structure and testing equipment is
already built and ready to use. Further projects related with this
one could take advantage of this apparatus, to take a second step
in the study of liquid fuel rocket engines. Now that there is a
first practical approach to the building of this type of engine, it
is more likely to have more projects extend the reach of this one.
This first approach to liquid fuel rocket engines can also allow
for larger scale models to be built and tested. Engines that
produce a thrust of up to 220 N could be tested in the actual test
structure, where the strain gage reaches its maximum deformation.
However, just by changing the cantilever bar that supports the
engine, bigger engines could be tested. Therefore, it is
recommended that further projects be developed to measure the
performance of the rocket engine. After this is done, and the
equations are proven good, larger engines could be built and the
construction of flight weight engines could be considered. 55.
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George P. Rocket Propulsion Elements. John Wiley & Sons, New
York, 2001. 7. COCKBURN, Sir Robert. La propulsion por cohetes y la
investigacin espacial. Taken from: Endeavour (Londres), Vol. 26 No.
97 Enero 1967. p. 21-26. 8. BECKWITH, Thomas G. Mechanical
Measurements. Fifth Edition. AddisonWesley Publishing Co., New
York, 1995. 9. INCROPERA, Frank P. Fundamentals of Heat and Mass
Transfer. Fifth Edition. John Wiley & Sons, Hobokem NJ, 2002.
56. ANNEX: BLUEPRINTS The following pages show the blueprints for
the different parts of the engine, pipes and support structure. 57.
IM-2006-II-0157 58. IM-2006-II-0158 59. IM-2006-II-0159 60.
IM-2006-II-0160 61. IM-2006-II-0161 62. IM-2006-II-0162 63.
IM-2006-II-0163 64. IM-2006-II-0164 65. IM-2006-II-0165 66.
IM-2006-II-0166 67. IM-2006-II-0167 68. IM-2006-II-0168 69.
IM-2006-II-0169 70. IM-2006-II-0170
