Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

52, 1, pp. 139-149, Warsaw 2014

INVESTIGATION OF AN ADDITIONAL OXIDIZER CHARGE EFFECT ON

SELECTED OPERATIONAL CHARACTERISTICS OF A SOLID-FUEL

ROCKET ENGINE

Andrzej Żyluk, Mariusz Pietraszek
Air Force Institute of Technology, Warsaw, Poland

e-mail: andrzej.zyluk@itwl.pl; pietrm@itwl.pl

The paper has been intended to discuss some issues closely related to the elimination of an
extremely disadvantageous phenomenon, i.e. the occurrence of a negative oxygen balance
in products of combustion emitted by a solid-fuel rocket engine while launching a missile
from the aircraft. Findings of experimental examination of such engines furnished with an
additional oxidizer charge have also been presented.

Key words: oxygen balance, rocket engine, aircraft, experimental examination, oxidizer
charge

1. Introduction

Intensivedevelopment of air armament technology enforces integration of newlydesignedaircraft
weapons with those that have already been in service. It always requires a series of tests to be
carried out to confirm effectiveness and operational safety of the weapon system in question.
One of numerous characteristics under examination, extremely important to air-launched

missiles, is how they affect the carrier. It is required that the air-launchedmissile do not disturb
the carrier’s flight and have no adverse impact on the operation of any of on-board systems
(Kurow and Dołżański, 1964; Stieczkin et al., 1961). Among the most frequent undesirable
effects of launching amissile from the carrier, is the stream of the rocket engine emitted exhaust
gas that affects operation of the aircraft turbine engine, which may even lead to the engine
stall/surge (Gajewski et al., 1980; Kowalski et al., 2011). This effect was observed withmissiles
powered by rocket engines supplied with high-energy solid fuels displaying negative oxygen
balance.Combustionproducts are, in this case, rich in incompletely burntparticles of carbonand
hydrogen; what is more, their temperature is ca. 926.8◦C (Leciejewski, 2010). In consequence,
these particles are rapidly burnt out in the air just behind the exhaust nozzle, which causes
oxygen deficit behind the moving missile (Torecki, 1989). Releasing the missiles in series from
the launch aircraft generates hot oxygen-free air region propagating behind the missiles, which
may lead to surge or flameout of the carrier’s engine (Nechaev et al., 1980; [14]). To prevent the
engine surge, efforts were initiated tomodify themissile-dedicated rocket engine. However, first
and foremost for economic reasons, only slight design alterations proved permissible, ones that
would not change aerodynamic and ballistic characteristics of the missile. Therefore, a decision
wasmade to embark on studies intended tomodify the oxygen balance of exhaust gas discharged
from the rocket engine, however, with nomodifications to the powder-pulp composition.

2. Theoretical analysis

One of the methods of altering the oxygen balance of combustion products from the rocket-
-propellant decomposition consists in the insertion of an additional portion of the oxidizer



140 A. Żyluk,M. Pietraszek

right into the combustion chamber. This method allows for some changes in energetic valu-
es/characteristics of combustion products from the rocket engine (temperature) with no modi-
fication in design of major structural components (assemblies, parts) of the rocket such as the
combustion chamber, the nozzle, or the igniter. This solution also preserves characteristics of the
interior ballistics (the operating pressure and the specific pulse). Qualitatively, the improvement
in the oxygen balance of the reaction of burning out the rocket combustion products is well
illustrated with comparison between:
a) the burn-out reaction that utilizes the air oxygen, with no oxidizer

2CO+3H2+2OH+2
(

O2+
0.79
0.21
N2
)

⇒ 2CO2+4H2O+2
0.79
0.21
N2 (2.1)

b) the burn-out reaction that utilizes an additional oxidizer in the form of the K2SO4 charge

K2SO4+2CO+3H2+2OH+2
(

O2+
0.79
0.21
N
)

⇒ 2CO2+3H2O+H2S+K2O+2O2+2
0.79
0.21
N2

(2.2)

The above written stoichiometric equations do not reflect the complexity of an actual com-
bustion process with the combustion products burn-out. However, they allow one to perform
qualitative analyses.
With the fact taken into account that rockets use a (nitro) polymeric fuel as the propellant,

specific characteristics of that fuel encouraged us to carry out the analysis of applicability of
potassium salts as oxidizers since they are inhibitors of natural initiation of the ignition of hot
hydrocarbons resulting from combustion products coming into contact with the atmospheric air.
Reactions of decomposition of potassium salts are endothermic, which allows for using them as
flash reducing agents to dim the burn-out flame. In practice, these salts may be introduced into
the solid propellant as an admixture or a separate charge placed externally inside the combustion
chamber of a rocket.The literature references report that in thecase theoxidizer is anadmixture,
the burn-outflame is fully suppressedwhen a 1.14%mass fraction (w/w) of potassiumnitrate or
4%of potassium sulphate is added to the propellant. Such admixtures are sufficient to hold back
the flames during the entire time of the rocket operation. In the second case, when an external
charge is placed inside the combustion chamber, such flame suppression lasts only 20% of the
entire time of the rocket engine operation. Themuch shorter time of complete flame suppression
achieved for the second case results from the fact that the oxidizer is placed in the zone of the
fuel combustion (flame) front, where temperature of gases reaches as much as 2426.8◦C, i.e.
it substantially exceeds the temperature of the K2SO4 decomposition (1688.8◦C, according to
Yang et al. (2000)). Under such circumstances, the decomposition process may be very violent,
the reaction time will depend on the radial thickness of the potassium sulphate charge. Since
the ratio of the fuel charge thickness to that of theK2SO4 charge is 2.75, the rate of the K2SO4
combustion (flame) frontwill behigher than the rate of fuel combustion (Bagrowski et al., 2011).
The effect of applying the flash reducing agent to dim the burn-out flame from the rocket

engine for the very same times from the engine start-up – in our case, the potassium nitrate
(KNO3) – is shown in Fig. 1.

3. Experimental examination

The subject of examination was a charge of the potassium sulphate (VI) salt. The process for
manufacturing such charges has been developed as well (Hawley, 2003). The process assumes
that a potassium sulphate charge is bonded together from a number of items compacted in the



Investigation of an additional oxidizer charge effect... 141

Fig. 1. Potassium nitrate affecting the exhaust gas burn-out – comparison of thermograms recorded at
the initial stage of the fuel-charge burning for various mass fractions (w/w) of KNO3 introduced in the

combustion chamber (mass fractions given in %)

form of bushes placed on a stainless steel rod. The compacted items are made of potassium
sulphate granulated into grains coated with some adhesive substance (binder). The granular
structure was developed on the basis of experiments and tests intended tominimize the content
of the binder and to acquire suitable physical properties of the compacted items. An average
total weight of the K2SO4 salt charge was 120.1g, whilst the weight of pure potassium salt was
105.1g. An average length of the salt chargewas 489.4mm.Three rocket engineswere subject to
examination., one of themwas providedwith the oxidizer charge. Location of theK2SO4 charge
inside the rocket engine is shown in Fig. 2.

Fig. 2. Cross-section of a rocket with a charge of K2SO4

Measurements of changes in both temperature of the exhaust jet and thrust of the rocket
engine were carried out on a vertical test stand. The rocket engine was fixed vertically in two
yoke clamps, with its exhaust nozzle directed upwards. The engine thrust was measured using
a measuring path with the piezoelectric sensor from the PCB Electronic as its key component
mounted in a socket of the support plate of the test stand. Measurements were recorded with
an oscilloscope. The recording was triggered by a voltage signal from the piezoelectric sensor
connected to one of the oscilloscope input channels. The masurements were stored as a text
file and then processed with the spreadsheet software [15]. The recorded changes in the engine
thrust with time were used to calculate the value of the total impulse of the rocket, according
to the formula

Ic =

tk
∫

tp

P dt (3.1)

where: Ic is the total impulse of the rocket, P – thrust, tk – time of termination of the engine
operation, tp – time of starting the engine.
Table 1 gives calculated values of total impulses of the rockets under examination.
Computations have been made for each experiment separately applying time intervals that

cover totals of measurements recorded (see Fig. 3).



142 A. Żyluk,M. Pietraszek

Table 1.Measured values of total impulses of the examined rockets

No. Engine lot Ic [Ns]

1 Engine from the 2nd lot as of 2006 6762
2 Engine from the 1st lot as of 2009 6716
3 Engine from the 2nd lot as of 2006, 6815
with K2SO4 oxidizer

Fig. 3. Thrust measurements

The foregoing results are consistentwith the value specified in the Specifications for the total
impulse of the rocket (­ 6.7kN); furthermore, they indicate that the oxidizer bar only slightly
affects, i.e. changes the engine thrust (Fig. 3),whichhas nopractical effect onballistic properties
of the rocket. The measurement has displayed a much higher engine thrust peak at the initial
stage of the engine run (Fig. 4). It may indicate that the rocket engine starts its operation
under erosion-attributable unsteady conditions, which is typical of engines, within which the
combustion process takes place on the lateral surface of the fuel (Kurow and Dołżański, 1964).
It may result from the fact that the oxidizer has been introduced in the already existing engine
chamber. The higher the fill factor of the combustion chamber (with the combustion process
taking place on the lateral surface of the fuel), the stronger tendency of the rocket engine to
change over to the unsteady mode of operation (see, e.g. Safta et al., 2011). Results of some
additional tests carried out both on the test bench and under field conditions (not described in
this paper) prove that the flow area increased by necking the rocket charge at the nozzle has
suppressed the above-described disadvantageous phenomenon, with no effect upon the thrust
value.

Fig. 4. Thrust measurements – the initial stage of rocket engine operation



Investigation of an additional oxidizer charge effect... 143

Temperature of the exhaust jet was measured using two independent measuring paths.
The first one comprised two nickel-chromium, type K, thermocouples from the Czaki Thermo-
Product and an oscilloscope to record the measurements taken. The thermocouples were atta-
ched to a fixed pole and aligned with the central axis of the tested rocket engine at distances
of 1.5m and 3m from the nozzle mouth. The thermocouples located in this way could measure
temperatures inside the flame of the exhaust gas burning out.
The recordingprocesswas triggered byavoltage signal fromthe control panel, normally used

to start rocket engines. Measurements were taken and recorded using two measuring channels
of the eCroy WJ334 oscilloscope. They were stored as a text file and then processed with the
spreadsheet software to gain a set of discrete values. An example of the set of temperature
changes with time is shown in Fig. 5.

Fig. 5. Changes in temperature recorded by thermocouples at the distance of 3m from the nozzlemouth

Fig. 6. Thermograms showing correspondingmoments of the rocket engine operation: with (left) and
without K2SO4 oxidizer charge applied (right)

Results of the examination of rocket engines with the K2SO4 charges inside were compared
with those obtained from tests of engines with no oxidizer bars inserted (Bagrowski et al., 2011).
The temperature measurements support the assumed thesis that an oxidizer charge inserted
in the combustion chamber of a rocket engine reduces the exhaust gas temperature. Changes
in temperature recorded during the examination indicate that the burning time of the K2SO4
oxidizer charge is ca. 600ms, whilst the flame temperature for the combustion with the oxidizer
activated was reduced down to 750K (477◦C). Figure 6 shows the process of the exhaust gas



144 A. Żyluk,M. Pietraszek

burnout as recorded in the course of the testing work, 0.2s after the rocket engine had been
started.
The second independent path to take temperaturemeasurements involved a set of two ther-

mal imaging cameras. Both cameras were located at the distance of 4m from the central axis of
the rocket engine. The 3-5µmspectral band thermovision images were recorded bymeans of the
FLIR SC6000 HSDR thermal imaging system with the InSb (Indium Antimonide) IR detector
with matrix resolution of 640× 512 pixels. The ND3 IR filter and the optics of focal length
of 25mm made the system complete. The system was calibrated for the temperature range of
100-1200◦C using the SR-800 Blackbody Control Master by the CI-Systems Inc. Sequences of
images were recorded with the frequency of 126Hz. The recorded data was then subjected to
processing by means of the RTools software from the FLIR Systems Inc. (Lubieniecka and Łu-
kasiewicz, 2011).
The following infrared images areas were selected for the thermographic analysis:

• the exhaust cone region – to estimate the exhaust gas temperature immediately after it
leaves the nozzle,

• the region of the exhaust jet, i.e. of the mixture of the exhaust gas and air – it is the
so-called burn-out region or the secondary-flame (‘backfire’) region,

• quasi-point region located at a distance of ca. 1m from the nozzle.

The switch-over from recording temperature variations at particular points to takingmeasu-
rements at ‘quasi-point’ surface regionswas intended toget ridof severe temperaturefluctuations
occurring in the course of some violently proceeding phenomena, e.g.:

• turbulent flow,

• burning of gases.

Both the substitution of points with regions of small surfaces and the read-outs of average
temperaturemade the interpretation of the results gained easier. Average temperature changes
with time have been determined.
The changes in temperature for the three above-listed engines (Figs. 7, 8, 9) are presented

below:

• region of the engine exhaust cone (Fig. 7) – exhaust gas temperatures are nearly identical
for all the engines and range from 496.8◦C to 526.8◦C; this proves that any admixtu-
re/additional charge remains of practically no effect on the exhaust gas temperature,

• region of the secondary flame (‘backfire’) (Fig. 8) and that at the distance of 1m from the
nozzle (Fig. 9) – for engines #1 and #2 the gas burning temperatures are quite similar
and the range from 796.8◦C to 846.8◦C,whereas behaviour of engine#3 remains different
from those two, i.e. nearly immediately after the rocket ignition (in ca. 50ms) there is a
drop in temperature from the initial ca. 796.8◦C to ca. 496.8◦C; the temperature remains
at this level for approx. 0.3s; for another 0.1s it rises up to the level of 796.8-846.8◦C,

• with analyses of the recorded changes as the basis, one can determine thermal parameters
typical for engine performance with reference to characteristic time intervals throughout
the entire engine operation:

– 0-0.1s – the engine start-up phase – it proceeds in a very similar way for all three
engines; characteristic of thisphase is temperature riseup tomaximumvalues of 896.8
K; for engines #1 and #2 the run-up phase terminates in the operating conditions
getting stabilized at the level just reached; for engine #3, however, a rapid drop in
temperature is recorded in some selected regions under control (496.8◦C-596.8◦C)
owing to the application of an additional oxidizer charge; the delay results from the
inertia of physical and chemical processes of the oxidizer material decomposition;



Investigation of an additional oxidizer charge effect... 145

– 0.5 to ca. 1.1s – all three engines produce similar changes in temperature – at a
distance of approx. 0.6m from the nozzle the temperature rises from 496.8◦C up to
796.8◦C, and then to 896.8◦C at the distance of approx. 1m;
– after approx. 1.1s – all three engines produce similar changes in temperature; the
temperature gradually decreases.

Fig. 7. Changes in exhaust gas temperature within the exhaust cone region

Fig. 8. Changes in exhaust gas temperature within the region of the secondary flame (‘backfire’)

Fig. 9. Changes in exhaust gas temperature at the distance of 1m from the nozzle



146 A. Żyluk,M. Pietraszek

Another phase of the work consisted in the examination of spectral characteristics of rocket
engines recorded with the SR-5000 spectral radiometer (Lubieniecka and Łukasiewicz, 2011).
Four rocket engines were subject to examination, two of them, No. 5 and No. 6, were provided
with oxidizer charges.

Determination of spectral characteristics proved to be extremely difficult since radiation of
the exhaust gas is a sophisticated phenomenon. The spectrum of any particular exhaust-gas
component is very complex. It reflects the complex and complicated nature of interactions of
ions of a gas molecule; the radiation itself can be related to particular vibrational modes of ion
oscillations – lateral and transverse vibrations.When spectra of particular components overlap,
the resulting spectral resolution proves to be relatively complicated. It should be emphasized
that the parameters of the spectral resolution are also affected by temperature. Another diffi-
culty arises from the fact that certain substances, e.g. CO and CO2 radiate in a very similar
way, and in practice, their spectral bands overlap. The next problem is the presence of water
vapour that generates hundreds of radiation bands over the entire infrared range. The infrared
spectrum analysis enabled us to identify major components of the exhaust gas mixtures from
the engines under examination.Molecules that have greatest shares in the IR radiation are those
of H2O,CO2 andCO. Figure 10 shows radiationwavelengths for components that substantially
contribute to the IR radiation of rocket engines. For two engines with the oxidizer inside, one
can easily see changes in the recorded radiation, which resulted from the reduction in tempera-
ture of the burning flame, and hence, the reduced amount of emitted radiation. The bandwidth
of 4.3 to 4.9µm is the area of particular interest since it covers radiation of both the CO and
CO2 within the abovementioned proportion of ca. 80% ofCO2 and 20% of CO.The substantial
reduction in the radiant power for that bandwidth for engines #3 and #4 as compared to the
adjacent bandwidth for CO (4.1-4.3µm) suggests that with the potassium sulphate applied less
amount of CO2 is produced in favour of CO. It means that the exhaust gases from the engines,
where the K2SO4 oxidizer was added, do not react with the ambient air.

Fig. 10. A spectrogram of the third scan (after ca. 300ms of combustion) for the wavelength range of
1-6µm for engines #3, #4, #5 and#6

The above is also confirmed in Fig. 11 that shows variations of the radiation power for
individual engines and functions of time. For themodified engines (with the oxidizer inside), the
radiation power is much less during the first moments after the missile engines kick off. After
having the mixture of salts combusted, the results are quite similar for all four engines. The
effect of K2SO4 is observed during the initial 400ms after ignition of the engines.

Themodified rocket engines (#5 and#6) demonstrated about fourfold reduction in the in-
frared radiant power (hence, reduction in the exhaust gas temperature) over approx. 400ms and
a substantial reduction in the carbon dioxide emission. The probable reason for this reduction



Investigation of an additional oxidizer charge effect... 147

Fig. 11. Changes in the radiant power against time while operating particular engines (time is reflected
by scan numbers, scans being spaced every 100ms)

in CO2 emission was that the temperature of the exhaust jet was lowered down to the level at
which the reaction

CO+
1
2
O2 =CO2 (3.2)

runs at a very low rate. That hypothesis is confirmed by the following observations:

• comparison between CO radiation intensities within the bandwidth of 4.1-4.3µm for mo-
dified and non-modified engines (over first 400ms of engine operation) gives the ratio of
ca. 0.45;

• the ratio of intensities of carbon dioxide emissions (the bandwidth of 4.3-4.9µm) by a
modified and a non-modified engine amounts to ca. 0.25.

Therefore, attenuation of the CO2 radiation bandwidth is much stronger than that of the
CO radiation bandwidth, which confirms the thesis that the oxidation of the carbon monoxide
is interrupted due to reduction in the exhaust gas temperature effected by the application of
potassium sulphate.

4. Conclusion

The experience gained while using the rocket missiles of the same type but different batches
(i.e. missiles manufactured on the basis of the same technical documentation) proves variations
in the level of risk that the engines of the aircraft and the missile launch platform system
would surge. This results from some differences in parameters of particular components used to
manufacture the rocket propellant – even in the case when these parameters are kept within a
certain acceptable limits. The nowadays used acceptance tests and equipment do not allow any
hazard of this kind to be detected at the manufacture level. This is the main reason why the
authors have decided to take a more global approach to the problem and solved it by applying
theK2SO4 charge.The introduction of an additional component in formof an oxidizer bar to the
combustion chamber of a solid-fuel rocket engine gives a substantial reduction in temperature of
the exhaust gases emitted by the engine andmitigation of the rocket engine exhaust gas burnout,
in particular of carbon dioxide.Measurements taken up to the present prove that thismethod of
reducing the burn-out flame remains irrelevant tomechanical, dynamic and ballistic parameters
of the rocket engine. Itmeans that improvements in theaircraft safety at themoment themissiles
are launched can be achieved by improvement in the oxygen balance. Hence, it seems reasonable
to furnish the missile power plant with an oxidizer bar, as described above. Obviously, such
a modification must be preceded with thorough in-flight examination/tests on the interactions



148 A. Żyluk,M. Pietraszek

between the weapon and the carrier. Moreover, lower temperature of the rocket engine exhaust
gases results in the reduced wear-and-tear of structural components of the missile launcher and
prolongation of its lifetime. Another advantage and argument for applying oxidizer bars is the
fourfold reduction in radiation generatedby the runningrocket engine.This considerably reduces
the capability of the enemy’s passive protection systems to detect a missile taking off from the
carrier.
Themajor reason for the authors’ effort was to prevent the hazard of surge while launching

missiles, which may result in setting fire to the aircraft or to the engine(s) shut-down, i.e. to
crash.
The above-formulated objective has been reached. In the nearest future, the authors are

going to proceed with the modelling of phenomena that take place in the combustion chamber
in the decompression region; also, with the optimisation of the structure of the K2SO4 charge
itself.

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Manuscript received June 6, 2013; accepted for print October 1, 2013