This paper proposes the use of micron-sized aluminum (pyral, average particle size 3.66 μm) with a higher specific surface area as a good candidate to enhance the burn rate of the composite propellant. Experiments were performed in the pressure range of 10 to 70 bar in a window bomb for measuring the burn rate. Comparison of these burn rate results with those obtained using micron- and nanosized aluminum found that the performance of pyral was in between that of micron- and nanosized aluminum. The reason for the high burn rates observed with pyral is due to the flake like appearance of pyral with a large specific surface area. It is argued that, if the specific surface area is large, then the thickness becomes the characteristic length scale. This ensures the heat release from the aluminum combustion to occur closer to the propellant surface as the thickness of pyral is in nanometers. Both the x-ray diffraction and heat of formation analyses indicated that pyral had higher purity than nanoaluminum, which has an implication to the specific impulse of the propellant. In addition to this, it shows that the micron-sized catalyst is effective with pyral, whereas it is ineffective with nanoaluminum. This study also reports the mechanical properties of the propellant containing pyral.

Periyapatna A. Ramakrishna

Department of Aerospace Engineering

Sumit Verma

ALUMINUM COMBUSTION

Average particle size

Characteristic length

Composite solid propellant

HEAT OF FORMATION

Large specific surface areas

PROPELLANT SURFACES

Specific impulse

Aluminum

Aluminum alloys

Composite propellants

Mechanical properties

Propellants

X ray diffraction

Specific surface area

IIT Madras is a public technical and research university located in Chennai, Tamil Nadu. Founded in 1959, it is recognised as an Institute of National Importance.

IIT Madras has been ranked as the top engineering institute in India for four years in a row by the National Institutional Ranking Framework of the MHRD

It currently offers undergraduate, postgraduate and research degrees across 16 disciplines in Engineering, Sciences, Humanities and Management. About 596 faculty belonging to science and engineering departments and centres of the Institute are engaged in teaching, research and industrial consultancy.

IIT Madras

Effect of Specific Surface Area of Aluminum on Composite Solid Propellant Burning

Journal of Propulsion and Power

Polytetrafluoroethylene is known to enhance the reactivity of aluminum. The enhancement in the reactivity is produced by mechanically activating the aluminum using polytetrafluoroethylene. In this study, mechanically activated aluminum powder is used along with paraffin wax as the fuel grain for a hybrid propellant. Here, gaseous oxygen is used as oxidizer. To achieve an optimum composition for the best specific impulse, the aluminum fraction in the composition is restricted to 50% of the base fuel composition along with 50% wax/ethylene vinyl acetate (combination of wax and ethylene vinyl acetate, in a ratio of 4∶1). The polytetrafluoroethylene in mechanically activated aluminum powder is added at the expense of wax/ethylene vinyl acetate in the fuel composition. When compared with the composition having pyral aluminum powder (which has flake like particles of very high specific surface area), mechanically activated powder increases the fuel regression rate by ∼40% at an oxidizer mass flux of 35 g∕cm2-s. It is also observed that the combustion efficiency of the hybrid motor is 59% with the use of mechanically activated aluminum powder in comparison to 39% obtained with micron-sized aluminum powder. Copyright © 2018 by Indian Institute of Technology, Madras, India.

Utilization of mechanically activated aluminum in hybrid rockets

This studymakes an attempt to demonstrate a technique to embed the catalyst on ammoniumperchlorate surface. In the present study, various techniques like differential scanning calorimeter, thermogravimetric analysis, scanning electron microscope, and x-ray computed tomography scan analysis as well as others were used to establish the effectiveness of this technique.Micron-sized iron oxide was used in this study for embedding the catalyst on ammonium perchlorate. Burn rates of pellets containing different fractions of iron oxide from various sources were measured to establish an optimumfraction for highest burn rate of ammoniumperchlorate pellets achievable with iron oxide. These burn ratesweremeasured using aCrawford bomb, and a fraction of1%iron oxide (Sigma-Aldrich)was highestamong them for pellets. The burn rate of the ammoniumperchlorate pellet with 1%iron oxide at 70 bar pressure recordedwas 13.33 mm/s. This fraction of iron oxide was also used to study the effect of embedding the catalyst on ammonium perchlorate surface when used in nonaluminized composite solid propellants. It is observed that catalyst-embedded ammonium perchlorate yields a higher burn rate as compared to the mechanically mixed catalyst. ©2017 by the American Institute of Aeronautics and Astronautics, Inc. All rights reserved.

Effects on burn rates of pellets and propellants with catalyst-embedded AP

The Heterogeneous Quasi One-dimensional (HeQu1-D) model for AP/HTPB composite propellant combustion is extended to aluminized propellants. Following the serial burning approach of HeQu1-D, a statistical particle path through an aluminized propellant is taken to consist of aluminized binder-matrix coated AP particles of various sizes. Extending the idea of homogenization of fine-AP particles, aluminum particles are assumed to be homogenized with the binder-matrix. Large Al particles (nominal size ≥ 15 µm) in the binder-matrix are assumed to get ejected into the gas phase and hence do not contribute to heat feedback to the burning surface. With these modifications, the model is shown to accurately predict the burn rate variation with pressure and initial temperature of propellants using Al of nominal sizes in the range of 15–50 µm (termed conventional aluminum, CAl). The experimentally observed reduction in propellant burn rate with substitution of AP by CAl is shown to be due to the increase in fuel richness and energy sink effect of melting of Al. Catalytic effects due to addition of burn rate modifiers (Fe2O3 in space shuttle booster propellant, for instance) are also accounted for by modifications to gas phase rate parameters. Increase in burn rate up to 25% with Al particles of a few µm (3–6 µm) in comparison with non-aluminized propellant is explained by recognizing that there will be non-negligible fraction of sub-micron Al due to the associated particle size distribution. This leads to heat release by sub-micron Al combustion close to the surface and an enhancement in the heat feedback, by a combination of convective and radiative mechanisms. Dramatic increase in burn rate with sub-micron Al (a factor of 4–5 as compared to CAl) is captured by invoking radiation from fine-Al/Al2O3 particles to propellant surface. Agglomeration of sub-micron Al particles is invoked to explain the saturation of burn rate enhancement with reduction in Al particle size and the effectiveness of sub-micron Al substitution in smaller fractions (bi-modal Al). Predictions for over fifteen different propellants with varying fractions of fine and coarse aluminum from earlier literature have been presented. Comparisons of the predictions from the model with experimental results from different sources is shown to be excellent-to-good for most cases. The hitherto unknown radiation dominated ablation (r˙&gt;50mm/s) of coarse AP particles and the effect of Al particle size on propellant temperature sensitivity are brought out. The MATLAB® code based on the model offers opportunity for design of AP-HTPB composite propellants with combination of fine and coarse aluminum with confidence. © 2018 The Combustion Institute

Combustion and Flame

Aluminized composite propellant combustion modeling with Heterogeneous Quasi-One dimensional (HeQu1-D) approach

An experimental investigation was conducted to study the combustion characteristics of aluminum and water, gelled using polyacrylamide as gelling agent. These propellants were tested for burn rates and residue in a Crawford bomb. The present study used flakelike aluminum particles with large specific surface area (∼22.5 m 2 ∕g) called pyral. Burn rates and residue were measured for oxidizer-to-fuel ratios (O/F) of 0.8, 1, and 1.2. Gelled propellants prepared with pyral had a maximum burn rate of 7.5 mm∕s at 60 bar pressure at an O/F of 0.8. However, these propellants had a very large residue of 70–80% of the initial mass. To overcome this, propellants were prepared with pyral, which was mechanically activated with polytetrafluoroethylene. The reduction in residue was mainly attributed to smaller thermal profile depth associated with mechanically activated aluminum and to the higher heat of combustion observed with such propellants. Through careful experimentation, the reason for the residue has been established to be due to heat loss from the sides of the propellant strand. The thermal conductivity and propellant diameter play a vital role in determining the heat loss from the condensed phase and in turn determining burn rates and residue. Copyright © 2018 by M. G. Gautham and P. A. Ramakrishna.

Combustion characteristics of aluminum–water gelled composite propellant

In this paper, experimental results of an aluminized fuel-rich propellant having energetics similar to boron-based fuel-rich propellant and having no residue after combustion are discussed. Using this aluminum-based fuel-rich propellant, which has higher density than the current fuels used for hypersonic flight, this paper looks at enhancing the Mach number envelope of a ramjet. Nondimensional thrust and drag calculations were carried out to identify the air-fuel ratio required for a Mach 6 flight, with different intakes accounting for different pressure recovery. Calculations were carried out with three different intakes, and it was observed that, even with the lowest pressure recovery of 9% at Mach 6, a hypersonic mission was possible. Values for various efficiencies were chosen with great care, and a perturbation analysis was carried out to make the calculations more robust. The specific impulse obtained with the aluminum-based fuel-rich propellant in ramjet mode was 515 s at a 25 km altitude. Comparison of an aluminum-based fuel-rich propellant in ramjet mode was made with a kerosene and hydrogen fueled scramjet from the specific impulse data available in the literature. The specific impulse of the aluminum-based fuel-rich propellant was nearly an order of magnitude higher as compared to a hydrogen fueled scramjet when adjusted to the density of hydrogen. Upon considering a system size, it was also shown that the aluminum-based fuel-rich propellant could meet the burn rate requirement for a Mach 6 flight. © 2017 by the American Institute of Aeronautics and Astronautics, Inc. All rights reserved.

Attaining hypersonic flight with aluminum-based fuel-rich propellant

Nano-aluminium particles of ∼50 nm size, produced at this laboratory, are added to composite solid propellants based on ammonium perchlorate and hydroxyl-terminated poly-butadiene binder that exhibit plateau burning rate trends and those including burning rate catalysts. The nano-aluminized propellant burning rates are compared with corresponding micro-aluminized and non-aluminized ones in the 1-12 MPa pressure range. The mid-pressure extinction of the matrixes containing the fine-sized ammonium perchlorate particles in the propellant along with the binder is investigated in all the cases to understand the mechanism of plateau-burning. Further, the variations in aluminium content, the aluminium size (within nano- and micro-ranges), bimodal combination of nano- and micro-aluminium are considered. Ferric oxide and titanium dioxide are the burning rate catalysts considered. Large scale accumulation of aluminium is observed not only in micro-aluminized matrixes, but also in nano-aluminized ones as clusters of 1-5 μm size. Since aluminium is added at the expense of the coarse ammonium perchlorate particles to preserve the total-solids loading in the present formulations, addition of micro-aluminium decreases the burning rate; whereas, nano-aluminized propellants exhibit ∼80-100% increase in the burning rate under most conditions. The near-complete combustion of nano-aluminium close to the burning surface of the propellant provides heat feedback that controls the burning rate. Mid-pressure extinctions of matrixes and plateau burning rates of propellants are washed out when nano-aluminium is progressively added beyond 50% in bimodal aluminium blends, but low pressure-exponents are observed in the nano-aluminized propellant burning rates at elevated pressures. Adjusting the plasticizer content in the binder alters the pressure range of plateau burning rates in non-aluminized propellants. Catalysts increase the burning rate by ∼50-100% in non-aluminized and micro-aluminized propellants, but in nano-aluminized propellants, the μm-sized catalyst does not affect the burning rate significantly; whereas, the nanometre size catalysts increases the burning rate merely by ∼5-15%. © 2009 The Combustion Institute.

Effect of nano-aluminium in plateau-burning and catalyzed composite solid propellant combustion

47th AIAA/ASME/SAE/ASEE Joint Propulsion Conference &amp; Exhibit

Role of moisture in activated charcoal in composite solid propellant

Effect of mixer size on density and burn rate of composite solid propellant

Nanotechnologies in Russia

Investigation of combustion of HEM with aluminum nanopowders

Journal of Hazardous Materials

Studies on the effect of plasticiser and addition of toluene diisocyanate at different temperatures in composite propellant formulations

Effect of specific surface area of aluminum on composite solid propellant burning

Journal	Journal of Propulsion and Power
ISSN	07484658
Open Access	No