U. Windberger1, L. Noirez2 1Medical University of Vienna, Vienna, 1090, Austria 2Paris-Saclay Universite, CEA-Saclay, Gif-sur-Yvette, 91191, France
Keywords: blood plasma, rheology, interfacial forces, boundary conditions, shear elasticity, endothelial surface layer
Results of an experimental study of blood properties are reported. To approach the boundary conditions of blood biophysics in a real flow, the viscoelastic measurements are carried out on surfaces coated with a 10-nm thick fibrous layer composed of extracellular matrix protein. For native whole blood, a plateau of the shear elastic modulus as a function of frequency is observed. It is concluded that a slow flow of blood plasma close to the vessel wall can generate a stationary plasma layer that contributes to the functional width of surface layers in blood vessels. The shear stress term calculated from the wall shear rate and blood viscosity becomes imprecise if it does not include the existence of this intermediate layer.
O.S. Dutova1, P.P. Bezverhiy2 1Kutateladze Institute of Thermophysics SB RAS, Novosibirsk, Russia 2Nikolaev Istitute of Inorganic Chemistry SB RAS, Novosibirsk, Russia
Keywords: viscosity, density, temperature, pressure, gas, liquid, krypton
Using the previously established dependence of the excess viscosity on the internal energy density, a simple low-parameter equation was obtained to describe the krypton viscosity coefficient in a wide range of state parameters. It was shown that the proposed low-parameter equation for calculating the viscosity coefficient of liquid and gas allows for reliable extrapolation beyond the limits of the studied area.
A. V. Baranovskii, G. A. Pribytkov, V. V. Korzhova
Institute of Strength Physics and Materials Science, Siberian Branch, Russian Academy of Sciences, Tomsk, Russia
Keywords: titanium, carbon, aluminum, thermal explosion, titanium carbide, titanium trialuminide, mechanical activation
Phase composition of thermal explosion products in compacts made of Ti-C-Al powder mixtures with an equiatomic ratio of titanium and carbon (soot) and with an aluminum content of 10 ÷ 40 % (wt.) is studied. The compacts are heated at a rate of 40 ± 5 °C /min in an argon atmosphere. Self-ignition temperature of all compositions was close to the melting point of aluminum (660 °C). Peak temperatures and the maximum rate at which temperature elevation becomes higher as the aluminum powder content in the mixtures increases. Synthesis products contain titanium carbide and Al3Ti titanium trialuminide, whose ratio depends on the aluminum content in the mixture. Pretreatment of reaction mixtures in a planetary mill flattens aluminum particles, thereby preventing the formation of a melt. The spreading of a melt over the titanium surface with subsequent reaction diffusion and the formation of Al3Ti increases the temperature in compacts made of nonactivated mixtures.
O. V. Lapshin, O. A. Shkoda
Tomsk Scientific Center, Siberian Branch, Russian Academy of Sciences, Tomsk,Russia
Keywords: powder mixture, mechanical activation, silicides, combustion wave
This paper describes experimental studies and a mathematical model of mechanical activation and high-temperature synthesis during the Nb-2Si combustion. The model is constructed in the macroscopic approximation. Synthesis regimes are determined depending on the duration of joint mechanical activation of the reagents. The kinetic parameters of pulverization of the initial powder mixture and the mechanochemical synthesis of the reaction product are obtained on the basis of experimental data by the inverse problem method.
P. A. Lazarev, M. L. Busurina, A. E. Sychev
Merzhanov Institute of Structural Macrokinetics and Materials Science, Russian Academy of Sciences, Chernogolovka, Russia
Keywords: intermetallic compounds, self-propagating high-temperature synthesis, microstructure, Al-Ti-Mn system, X-ray diffraction analysis
Alloys based on the Ti-Al-Mn ternary system are among the most important in the development of doped titanium alloys for various purposes. In this work, an alloy made of 42.9 % of Ti, 24.3 % of Al, and 32.8 % of Mn (by wt.) is obtained via self-propagating high-temperature synthesis (SHS) during a thermal explosion. X-ray diffraction analysis shows that the final synthesis product containsa cubic TiMn0.32Al2.68 phase, a hexagonal TiMn0.755Al1.246 phase, and a binary Mn3Al2 phase. The porosity of synthesized samples is rather high ≈41 %), and they contain many pores (up to 300 ÷ 400 μm). Phase formation may be due to the fact that the maximum temperature reached during the combustion of this system in the SHS process is insufficient for complete interaction with the formation of a Mn2Ti intermetallic phase and the dissolution of aluminum Al in it with the formation of a solid solution (Mn, Al)2Ti. This promotes the formation of intermediate intermetallic phases, which can be in equilibrium with the liquid phase up to a melting point of titanium.
V. M. Levin, L. L. Kartovitskii, A. A. Yakovlev
Moscow Aviation Institute (National Research University), Moscow, Russia
Keywords: combustion chamber, ramjet engine, fire test, attached air duct, thrust meter, system of distributed supply of liquid fuel, vortex formation, thermal protection, adjustable nozzle
This paper presents an analysis of approaches to ensuring the performance of a ramjet combustor using an unconventional method of measuring the axial force in testing a liquid-fuel combustor model under flight conditions simulated by a fired heater. The thrust and drag of the combustor model were measured in fire tests on an attached air duct using an axial force meter. Thrust is a parameter that characterizes the energy potential of any engine. In the conventional method, lengthy multi-parameter studies and calculations of performance are required to get an idea of the thrust and economic characteristics of a heat engine. The new method allows one to determine the effect of any parameter or structural element on the physical process in a combustor in units of the thrust force and evaluate the change in any parameter by the thrust level directly in fire tests. Using the proposed thrust measurement system at an initial stage of testing, one can clarify the direction of the search for the organization of the workflow and reduce the amount of intermediate calculations, saving a huge amount of time and money. This, combined with measurements of static pressure along the length of the combustor, allows a guaranteed prediction of the direction of search for improving the workflow efficiency. The ways to improve the workflow efficiency in a ramjet combustor using a thrust meter to evaluate the overall engine performance under conditions of limited technical and methodical possibilities in fire tests of the combustor are discussed.
A. N. Kudryavtsev, A. V. Kashkovsky, A. A. Shershnev, Yu. V. Kratova
Khristianovich Institute of Theoretical and Applied Mechanics, Siberian Branch, Russian Academy of Sciences, Novosibirsk, Russia
Keywords: numerical simulation, gas suspension, spin detonation
Three-dimensional numerical simulation of a detonation wave propagating in a circular tube filled with a gas suspension of aluminum particles in oxygen is performed with the use of the HyCFS-R code developed by the authors for modeling on hybrid computational systems. The regime of propagation with a single-head spin is reproduced. It is shown that combustion occurs in a certain localized front zone rotating during front propagation, which is typical for spin detonation in both purely gaseous mixtures and heterogeneous media. Data on the basic parameters of detonation wave propagation in a gas suspension of aluminum particles in the spin detonation mode are obtained. Comparisons with theoretical predictions and with numerical and experimental results of other researchers are performed.
G.-Z. Xu1, X.-D. Gao2, G.-L. Jin3, D.-Q. Wang1, Z.-M. Zhang1, T.-Y. Tan1, Y. Qin1, J. Liu1, F.-S. Li1 1National Special Superfine Powder Engineering Research Center of China, School of Chemistry and Chemical Engineering, Nanjing University of Science and Technology, Nanjing, China 2Gan Su Yin Guang Chemical Industry Group Co. Ltd, Baiyin, China 3Gan Su Yin Guang Chemical Industry Group Co. Ltd, Baiyin,China
Keywords: nano-RDX, RDX-based PBX, compressive property, detonation property, mechanical properties
Industrial micron-size hexahydro-1,3,5-trinitro-1,3,5-triazine (m-RDX) has been widely used in RDX-based polymer-bonded explosives (PBX). However, m-RDX results in poor mechanical properties and adhesive properties of RDX-based PBX m-RDX-PBX). Nano-RDX (n-RDX) has a small particle size and a large specific surface area, which provides a larger contact area with the polymer system. Thus, the porosity and compressive properties of PBX are improved if n-RDX is used in RDX-based PBX (RDX-PBX). In this study, m-RDX and n-RDX are used in RDX-PBX. The microstructure, component content, compressive properties, sensitivity properties, and detonation properties of RDX-PBX are investigated. The results show that n-RDX can make RDX-PBX more compact than m-RDX. The strain of n-RDX-based PBX (n-RDX-PBX) is increased by 39.7 % as compared to that of m-RDX-PBX. Meanwhile, the content of each component in n-RDX-PBX is consistent with that of the formula. The sensitivity of n-RDX-PBX is lower as compared to that of m-RDX-PBX, whereas the detonation velocity, detonation pressure, and detonation heat of n-RDX-PBX are equivalent to those of m-RDX-PBX.
Z.-S. Wang, Q. Jing, Q.-M. Liu, Y. Shen, C.-Q. Liu
State Key Laboratory of Explosion and Science, Beijing Institute of Technology, Beijing, China 1093503798@qq.com
Keywords: temperature, LX-04 explosive, shock initiation, Ignition and Growth model, thermal effect, impact sensitivity
Explosives are often exposed to war environments at different temperatures. The shock initiation characteristics of explosives are related to their properties and the ambient temperature in which they are located. In the present work, the parameters of the Ignition and Growth model of the LX-04 explosive at different temperatures are determined, based on the shock initiation experiments at different temperatures. Furthermore, the impact sensitivity simulation of LX-04 at initial temperatures of 25, 60, 100, 150, and 170 °C is carried out, and the critical impact velocity at these initial temperatures is found to be 325, 280, 233, 201, and 194 m/s, respectively. Based on the present simulation data, a new model for the relationship between the critical impact velocity and initial temperature is proposed. In addition, the initial temperature of the explosive has an important effect on the detonation performance: the higher the initial temperature, the higher the impact sensitivity of LX-04, and the higher the peak temperature of detonation.
S. D. Gilev
Lavrentyev Institute of Hydrodynamics, Siberian Branch, Russian Academy of Sciences, Novosibirsk, Russia
Keywords: electrical resistance, specific electrical resistance, aluminum, shock compression, high pressures and temperatures
Experimental data on the electrical resistance of aluminum under shock compression are analyzed. The electrical resistance of two types of aluminum foil located in dielectrics with different shock impedances is measured by the electrical contact method. The resultant dependences of the electrical resistance of aluminum on the shock wave pressure are monotonically increasing functions of pressure. However, the dependence of the specific electrical resistance of aluminum on the shock wave pressure can be monotonic (foil in Plexiglas) or nonmonotonic (foil in fluoroplastic). In the latter cased, the specific electrical resistance first slightly decreases with an increase in pressure and then increases. This behavior can be explained by the competing effects of compression and temperature heating on the specific electrical resistance. Due to shock compression of metal foil in the dielectric with a smaller shock impedance (Plexiglas), the measured electrical resistance is greater than that in the dielectric with a greater shock impedance (fluoroplastic). This result is caused by the greater temperature heating of metal foil in Plexiglas. The reasons for the qualitative difference in the behavior of the specific electrical resistance of metal under static and dynamic compression are discussed.