On Shear Rheology of Gel Propellants

Rahimi, Shai; Peretz, Arie; Natan, Benveniste

doi:10.1002/prep.200700018

Cited by 64 publications

(25 citation statements)

References 23 publications

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“…2 and 3 show a similar shear thinning trend with increase in the shear rate for the shear rate range 1 to 1000 1/s, to the reference Figure 4 [7]. The gelation of hydrogen peroxide [7] (Figure 4) was done using fine powder silica with a standard tapped density of approximately 50 g/l as a gelling agent, in a concentration ranging between 5 to 7 wt% [6,7], and it has a shear apparent viscosity range between 107 Pa.s and 100 Pa.s. Summaries of the results obtained for the apparent viscosity and yield stress of H 2 O 2 -SiO 2 gel for various temperatures are presented in Tables 1, 2, and 3.…”

Section: Determination Of Apparent Viscositysupporting

confidence: 61%

“…The clear understanding of fluid flow characteristics is vital for efficient combustion, in order to gain optimum performance. As a result, a significant effort has been made worldwide to formulate, prepare, and study the rheological properties of gel propellants for various applications in rocket propulsion systems [1][2][3][4][5][6][7]. In the current study, hydrogen peroxide based gel is examined and discussed, because it is eco-friendly.…”

Section: Introductionmentioning

confidence: 99%

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Rheological Characterization of Hydrogen Peroxide Gel Propellant

Jyoti¹,

Baek²

2014

International Journal of Aeronautical and Space Sciences

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An experimental investigation on the rheological behavior of gelled hydrogen peroxide at different ambient temperature (283.15, 293.15 and 303.15 K) was carried out in this study. The gel propellant was rheologically characterized using a rheometer, in the shear rate ranges of 1 to 20 s -1 , and 1 to 1000 s -1 . Hydrogen peroxide gel was found to be thixotropic in nature. The apparent viscosity value with some yield stress (in-case of shear rate 1 to 20 s -1 ) drastically fell with the shear rate.In the case of the shear rate range of 1 to 20 s -1 , the apparent viscosity and yield stress of gel were significantly reduced at higher ambient temperatures. In the case of the shear rate range of 1 to 1000 s -1 , no significant effect of varying the ambient temperature on the gel apparent viscosity was observed. The up and down shear rate curves for hydrogen peroxide gel formed a hysteresis loop that showed no significant change with variation in temperature for both the 1 to 20 s -1 and the 1 to 1000 s -1 shear rate ranges. No significant change in the thixotropic index of gel was observed for different ambient temperatures, for both low and high shear rates. The gel in the 1 to 20 s -1 shear rate range did not lead to a complete breakdown of gel structure, in comparison to that in the 1 to 1000 s -1 shear rate range.

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Section: Determination Of Apparent Viscositysupporting

confidence: 61%

Section: Introductionmentioning

confidence: 99%

Rheological Characterization of Hydrogen Peroxide Gel Propellant

Jyoti¹,

Baek²

2014

International Journal of Aeronautical and Space Sciences

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“…Apart from the reactivity aspects, the characteristics of solid fuels should be considered to ensure they can withstand the high heat load due to the combustion. This kind of consideration is found for gels dedicated to other propulsion techniques [75] but still remains absent for the hybrid rocket. For the thermal resistance, the melting temperature and the thermal conductivity are the most important data.…”

Section: Mechanical and Physical Characteristics Of Reducersmentioning

confidence: 99%

Literature survey for a first choice of a fuel-oxidiser couple for hybrid propulsion based on kinetic justifications

Gascoin

Gillard

Mangeot

et al. 2012

Journal of Analytical and Applied Pyrolysis

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“…The physical properties of the simulant gels (non-Newtonian fluids) are from [22]. The power-law model is used to describe dynamic viscosity, the correction is as follows:…”

Section: Gel Propellant Rheologymentioning

confidence: 99%

Numerical Simulation on Head-On Binary Collision of Gel Propellant Droplets

Liu

et al. 2013

Energies

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Binary collision of droplets is a fundamental form of droplet interaction in the spraying flow field. In order to reveal the central collision mechanism of two gel droplets with equal diameters, an axi-symmetric form of the Navier-Stokes equations are firstly solved and the method of VOF (volume of fluid) is utilized to track the evolution of the gas-liquid free interface. Then, the numerical computation model is validated with Qian's experimental results on Newtonian liquids. Phenomena of rebound, coalescence and reflexive separation of droplets after collision are investigated, and structures of the complicated flow fields during the collision process are also analyzed in detail. Results show that the maximum shear rate will appear at the point where the flow is redirected and accelerated. Rebound of droplets is determined by the Weber number and viscosity of the fluid together. It can be concluded that the gel droplets are easier to rebound in comparison with the base fluid droplets. The results also show that the alternant appearance along with the deformation of droplets in the radial and axial direction is the main characteristic of the droplet coalescence process, and the deformation amplitude attenuates gradually. Moreover, the reflexive separation process of droplets can be divided into three distinctive stages including the radial expansion, the recovery of the spherical shape, and the axial extension and reflexive separation. The variation trend of the kinetic energy is opposite to that of the surface energy. The maximum deformation of droplets appears in the radial expansion stage; in the case of a low Weber number, the minimum central thickness of a droplet appears later than its maximum deformation, however, this result is on the contrary in the case of a high Weber number. OPEN ACCESSEnergies 2013, 6 205

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On Shear Rheology of Gel Propellants

Cited by 64 publications

References 23 publications

Rheological Characterization of Hydrogen Peroxide Gel Propellant

Rheological Characterization of Hydrogen Peroxide Gel Propellant

Literature survey for a first choice of a fuel-oxidiser couple for hybrid propulsion based on kinetic justifications

Numerical Simulation on Head-On Binary Collision of Gel Propellant Droplets

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