The performance and stability of liquid rocket engines is often argued to be significantly impacted by atomization and droplet vaporization processes. In particular, combustion instability phenomena may result from the interactions between the oscillating pressure field present in the rocket combustor and the fuel and oxidizer injection process. Few studies have been conducted to examine the effects of oscillating pressure fields on spray formation and its evolution under rocket engine conditions. The pressure study is intended to address the need for such studies. In particular, two potentially important phenomena are addressed in the present effort. The first involves the enhancement of the atomization process for a liquid jet subjected to an oscillating pressure field of known frequency and amplitude. The objective of this part of the study is to examine the coupling between the pressure field and or the resulting periodically perturbed velocity field on the breakup of the liquid jet. In particular, transverse mode oscillations are of interest since such modes are considered of primary importance in combustion instability phenomena. The second aspect of the project involves the effects of an oscillating pressure on droplet coagulation and secondary atomization. The objective of this study is to examine the conditions under which phenomena following the atomization process are affected by perturbations to the pressure or velocity fields. Both coagulation and represent a coupling mechanism between the pressure field and the energy release process in rocket combustors. It is precisely this coupling which drives combustion instability phenomena. Consequently, the present effort is intended to provide the fundamental insights needed to evaluate these processes as important mechanisms in liquid rocket instability phenomena

Jacobs, H. R.

Santoro, R. J.

English

NASA Technical Reports Server

PRESENTATION 2.2.5
N91-28226
SPRAY COMBUSTION UNDER
OSC_TORY PRESSURE CONDITIONS
663
https://ntrs.nasa.gov/search.jsp?R=19910018912 2020-03-19T17:28:19+00:00Z

SPRAY COMBUSTION UNDER OSCILLATORY PRESSURE CONDITIONS
H. R. Jacobs and R. J. Santoro
Department of Mechanical Engineering
I. Research Objectives and Potential Impact on Propulsion
The performance and stability of liquid rocket engines is often argued to be
significantly impacted by atomization and droplet vaporization processes. In particular,
combustion instability phenomena may result from the interactions between the
oscillating pressure field present in the rocket combustor and the fuel and oxidizer
injection process. Few studies have been conducted to examine the effects of oscillating
pressure fields on spray formation and its evolution under rocket engine conditions. The
present study is intended to address the need for such studies. In particular, two
potentially important phenomena are addressed in the present effort. The first involves
the enhancement of the atomization process for a liquid jet subjected to an oscillating
pressure field of known frequency and amplitude. The objective of this part of the study
is to examine the coupling between the pressure field and/or the resulting periodically
perturbed velocity field on the breakup of the liquid jet. In particular, transverse mode
oscillations are of interest since such modes are considered of primary importance in
combustion instability phenomena.
The second aspect of the project involves the effects of an oscillating pressure field
on droplet coagulation and secondary atomization. The objective of this study is to
examine the conditions under which phenomena following the atomization process are
affected by perturbations to the pressure or velocity fields. Both coagulation and
secondary atomization affect droplet vaporization processes and consequently can
represent a coupling mechanism between the pressure field and the energy release
process in rocket combustors. It is precisely this coupling which drives combustion
instability phenomena. Consequently, the present effort is intended to provide the
fundamental insights needed to evaluate these processes as important mechanisms in
liquid rocket instability phenomena.
Due to the challenging measurement environment presented by these studies, a
complementary diagnostic development effort has proceeded in parallel with the above
studies. These diagnostic approaches are emphasizing real-time measurements of
droplet size, size distribution and spatial location. Both novel, as well as state-of-the-art,
techniques are presently being addressed and validated in the present experiments.
The major impact of the present study on propulsion engineering involves the
potential for gaining a fundamental understanding of the role of pressure variations on
atomization and spray phenomena. Through an understanding of the proposed
mechanisms for combustion instability generation, the basic understanding of the
underlying physics required for development of appropriate submodels can be achieved.
Present rocket combustion modelling efforts suffer from the lack of appropriate
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PRECEDING PAGE BLANK NOT RLMED
submodelsfor describingthe interactions between spray formation and droplet
processes with oscillating pressure and veloc_ fields. The present research program is
aimed directly at resolving some of the critical elements in that process.
666
I1. Current Status and Results
A Jet Breakup Under AcousticPressure Oscillations
A sequence ofexperimentshave been conducted to study the effectsof acoustic
oscillationson the breakup ofliquidjetsand the trajectoriesofthe resultingdroplets.
Both mono-injector(waterinjection)and co-axialnozzles (watercore;nitrogenannulus)
were investigatedtowards thisend. Experimentaltechniques used forthisinvestigation
involvedhigh speed cinematography (SpinPhysics camera), laserlight
scattering/polarizationratiotechniquesand simpleflashphotography. A new innovative
technique thatwillbe used inthe near futureisphase-doppler anemometry fordroplet
sizing.Experimentalresultsforthe mono-injectornozzles show thathigh frequency
acousticoscillations(I-4kHz) playa dramatic roleinthe breakup of liquidjetsat certain
preferential modes that are characteristic of the injection chamber. These results are of
potential importance for impinging-element type injectors for obvious reasons. Initial
experimental results for the co-axial nozzle have shown no dramatic changes in liquid
atomization characteristics. However, measurement capabilities have been limited in
these initial experiments and more exhaustive consideration is to be given to effects on
the droplet field in the near future. Preliminary numerical calculations indicate that the
trajectories of small droplets (less than approximately 100 #m) are significantly affected
both by acoustic oscillations and the phase angle of the oscillations at the moment of
atomization. Numerical calculations also show that these small droplets are subjected to
extremely high g-forces, which suggests that acoustic oscillations can trigger secondary
atomization phenomenon.
Experimental _;etup
A schematic of the cylindrical chamber used for our experiments is shown in Fig. 1.
The 6 inch diameter, 24 inch steel chamber has two 120-Watt Altec-Lansing speakers
attached at the ends of the speaker arms. These speakers are used to drive the
acoustic modes in the chamber. The speakers can be driven with any desired phase
separation and microphone measurements of the pressure field within the chamber show
that peak to peak oscillations in excess of 4 psi can be maintained. Two windows,
centered 6 inches from the top of the chamber provide visual access. Optionally, one of
the speakers can be replaced with a window to provide additional visual access. A
moveable injector as shown in Fig. 1 is used to position the injector face near the
window for added visual access. Four circumferential microphone ports, at 90" intervals
are located 10 inches from the top of the chamber. Microphones employed at these
ports are used to study the acoustic characteristics of the chamber.
The acoustic modes of the chamber were first identified both analytically and
experimentally. The standing wave frequencies were calculated by solving the 3-D wave
equation by separation of variables, For the experimental identification of the standing
wave frequencies, a white noise generator was used to drive the speakers and the
resulting microphone responses at the various ports were analyzed. Good agreement
between the calculations and experimental results were found for the simple longitudinal
and tangential modes. The higher combined modes of the chamber were, however, more
difficult to identify and is a reflection of the rich frequency characteristics of the chamber.
667
Fig. !.
cq
0
0
<
A schematic of the injection chamber.
668
_et Breakup Results
Acoustic oscillations were visually and photographically observed to dramatically
breakup the liquid jet emanating from mono-injector nozzles (0.0625 inch and 0.1 inch
diameter nozzles with a length to diameter ratio in excess of 10) in two distinct fashions.
The Reynolds numbers of the jets ranged from 2000 to 9000 and the corresponding
Weber numbers based on the gas density ranged from 0.03 to 0.5, which places these
jets in the Rayleigh breakup region. The first type of breakup occurred at 1140 Hz which
corresponds to the first tangential mode. The jet was observed to breakup into a spray
with droplet diameters of the same order of magnitude as the nozzle diameter. A
photograph of this tangential-mode breakup is shown in Fig. 2. The corresponding
pressure amplitude pattern at one phase angle measured by traversing two microphones
within the chamber is shown in the inset graph. Note that the centerline of the chamber
that bifurcates the speaker axis also delineates the positive and negative pressure
amplitudes. This type of pressure pattern indicates that the mode is 1-T mode. It is
postulated that the 1-T mode frequency couples preferentially to the breakup frequencies
of the jet. The second type of breakup is shown in Fig. 3 at a frequency of 1560 Hz.
For this type of breakup, the jet first acquires the shape of a two-dimensional fan
(perpendicular to the speaker axis) which is reminiscent of the fan-structure observed
with impinging nozzles. Droplets sheared from the bottom of the fan are visually at least
more than an order of magnitude smaller than the diameter of the nozzle. Acoustic
measurements of the mode in question show tangential mode-like characteristics as can
be seen from the inset graph in Fig. 3. However, the sharp pressure gradient that exists
along the center vertical plane of the chamber that seems to cause the jet to 'fan' out is
not characteristic of a pure tangential mode. This mode could be the 3-Longitudinal/I-
Tangential (calculated to be 1580 Hz) mode. Note that the pressure amplitude
measurements were made 10 inches from the top of the chamber which places the
measurement location close to the pressure antinode for the longitudinal component of
this mode.
Conclusions
Jets emanating from mono-injector nozzles were seen to breakup under both
tangential mode and mixed longitudinal/tangential acoustic modes into both spray-like
and fan-like structures for physical conditions that place the jets in the Rayleigh brea_(up
region. No effect of these modes on the gross atomization characteristics of co-axial
nozzles were observed. However, calculations indicate that trajectories of drop{ets are
affected by acoustic oscillations and it seems that measurements of droplet size and
velocity in lieu with the phase angle of acoustic oscillations will unearth additional
information.
B. Diagnostic Development
As a complementary effort to the atomization and spray studies described
previously, a diagnostic development program has been initiated to support the
measurement needs of this project.
Spray and droplet measurements in liquid rocket engines require non-intrusive
669
IFig. 2.
Spray type breakup observed at a frequency of 1140 Hz. The inset graph shows the
pressure amplitude at a horizontal plane (within the chamber) l0 inches from the top of the
chamber at zero phase angle. This mode is identified to be the first tangential mode.
670
Fig 3. Fan type breakup observed at a frequency of 1560 Hz. The inset graph shows the pressure
amplitude at a horizontal plane (within the chamber) 10 inches from the top of the chamber
at zero phase angle. Note the high pressure gradient at the center vertical plane. This
mode could be the third longitudinal/first tangential mode.
671
techniques which possess both high spatial and temporal resolution capabilities. In
addition, due to the short duration and highly transient nature of liquid rocket combustion
processes, techniques which provide extensive spatial measurement capabilities are
highly desirable. Recent progress in the development of planar laser imaging techniques
have demonstrated the potential for achieving such measurements. In the present work,
a planar laser imaging approach for droplet and particle sizing which incorporates an
optical polarization ratio technique has been investigated. A series of pressure atomized
sprays have been imaged to obtain droplet size measurements based on the ratio of
horizontally to vertically polarized scattered light. This technique, which provides an
ensemble averaged droplet diameter, provides spatially and temporally resolved droplet
size measurements over an extensive spatial region.
.Experimental Setup
The polarization ratio approach utilized in these studies involves a pulsed Nd-YAG
laser operating at the 532 nm laser line. This laser beam is formed into a sheet of light
whose polarization orientation is adjusted using a half-wave plate to provide both
vertically and horizontally polarized light components. For the water sprays studied, the
polarization vector was oriented at a 45" angle with respect to the horizontal plane of
polarization. The images of scattered light intensity at a 90" scattering angle were
simultaneously obtained for each polarization orientation using a pair of 35 mm cameras
with the aid of an appropriate beam splitter and polarization filter. The images were
recorded on black and white film and were subsequently digitized using a CID solid state
camera. These digitized images were stored on a personal computer and two-
dimensional polarization ratio fields were constructed from the ratio of a pair of vertically
and horizontally polarized scattered light images. The ratio of horizontal and vertical
polarization intensity can be directly related to appropriate optical scattering cross
sections (C,,/Cw). Droplet size information can be directly calculated from MIE light
scattering theory. Calculations of these polarization ratio values were utilized to provide
droplet size information throughout the spray.
Resu s
In the present studies, a spray region, 5 cm x 5 cm, was imaged and analyzed.
Droplet sizes based on D3z, in the water spray were observed to vary between 10 #m in
the central region of the spray to 40/_m near the edges of the spray. Comparisons with
preliminary measurements utilizing a phase doppler particle sizing approach consistently
show a systematic difference in size. The polarization ratio approach typically results in
droplet sizes a factor of two to four smaller than the phase doppler results. In addition
to providing a sizing capability, the present work demonstrates that the polarization ratio
approach can be used to provide a means to discriminate regions containing soot
particles from droplet regions. Such a capability will be useful in studies in liquid
hydrocarbon rocket combustors where both soot particles and droplets are likely to be
present.
672
IlL Proposed Work for Coming Year
Work during the next year will concentrate on performing similar acoustic
experiments in an environment that more closely matches actual rocket motors. These
experiments will be carried out in a pressurized environment using the current acoustic
chamber which can be operated at pressures up to 300 psi. Three types of nozzles will
be used: a series of mono-injector nozzles ranging in diameter from 0.0625 inches to 0.1
inches with an aspect ratio of at least 10, a co-axial injector having an inner diameter of
0.1 inches and an outer diameter of 0.2 inches with an aspect ratio of 35, and an
impinging nozzle yet to be desiged. Based on past experience, the acoustic modes of
interest with the current chamber will be the first tangential mode (1-T mode) at 1140 Hz
and the previously discussed first tangential, third longitudinal mode (1-T/3-L mode) at
1560 Hz.
The acoustic drivers will be upgraded to provide a greater pressure field intensity in
order to allow other standing wave modes to emerge, such as radial modes. Present
observations have shown that as the jet velocity increases, the effect of the applied
acoustic field on the spray diminishes. By using more robust acoustic drivers, the mean
jet velocity can be increased with the instability effect remaining. In addition, fluids such
as Freon 112 and Freon 113 will be used to simulate actual rocket motor fuels and
oxidizers.
In terms of measurement techniques, a variety of approaches will be employed
including microphone probes for characterizing the induced pressure field, while flash
photography, high-speed cinematography, a two-dimensional laser polarization ratio
technique, and a laser-based phase doppler particle analyzer will be used to characterize
any observed spray instabilitiy phenomena. The photographic techniques yield a global
view of the interaction between the applied acoustic field and the injected fluid, whereas
the laser techniques allow for quantitative measurements of the observed spray
phenomena.
A two-dimensional polarization ratio technique is currently being developed to
acquire droplet size data under transient combustion conditions. This technique is
based on a thin sheet of laser light emanating from a frequency doubled Nd:YAG pulse
laser illuminating a spray. The two-dimensional polarization ratio technique determines
the droplet diameter in the plane of the laser sheet using the measured polarization ratio
of the scattered laser light from spherical liquid droplets in the spray. In essence, the
polarization ratio technique gives spatially extensive droplet size data with high temporal
resolution.
The phase doppler particle analyzer uses an Ar-ion laser to maintain a non-intrusive
probe volume in a given environment and provides a point measurement of the droplet
size in the spray. The phase doppler particle analyzer will continuously record droplet
size and velocity distributions inside the probe volume with respect to the phase of the
acoustic oscillation.
673
Thus by using the above two laser diagnostic techniques, a quantitative
determination of the effect of the induced pressure field on the spray can be obtained.
The techniques provide complementary information and measurement verification
concerning the evolution of the spray in the oscillating pressure field.
Concurrent with the continued acoustic instability work in the current chamber, a
new transparent rectangular chamber will be constructed. One of the difficulties with the
current cylindrical chamber is its 'rich' frequency characteristics. By fabricating a
chamber in which the consecutive standing wave frequencies are equally spaced, one
can easily locate acoustic modes of interest with a standard frequency generator. The
transparent nature of the new cell will allow more optical and visual access to utilize the
proposed measurement techniques. In addition, the new cell will allow easier access for
microphone probes.
The objective of these experiments will be to better understand the interaction
between an oscillating pressure field and the atomization and spray phenomena in rocket
combustors. Continued attention will be given to the study of the observed coupling
between the pressure field and the breakup of liquid jets as described previously in the
results section. However, additional attention will be given to the study of droplet-droplet
interactions such as coagulation and secondary breakup which may follow the
atomization process. These measurements will be conducted under conditions similar to
the liquid break-up studies and will concentrate on quantitative droplet size
measurements using the described laser-based techniques.
674
PRESENTATION 2.2.6
LIQUID JET BRFAKIYP
AND
ATOMIZATION IN ROCKET CHAMBERS
UNDER DENSE SPRAY CONDITIONS
675



Spray combustion under oscillatory pressure conditions

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