A consistent mesh refinement study, relating to the prediction of aerodynamic forces about an experimentally 13 validated reference train geometry, is presented in this paper. The flow about a high-speed train has a multi-scale 14 character which poses challenges for the design of computationally effective meshes. The purpose of this study is to 15 assist in the development of guidelines for effective drag prediction of high-speed trains using numerical simulation. 16 These guidelines should assist CFD practitioners by identifying the regions of the mesh that are critical for the correct 17 estimation of drag as well as providing information on appropriate mesh characteristics, such as volume and surface 18 element length scales. Numerical assessments are validated against an experimental drag measurement program and 19 the extent to which RANS is sufficiently predictive for industrial design is discussed. The results obtained in the work 20 suggest that the mesh about the train nose is essential for the proper assessment of the aerodynamic drag acting on the 21 vehicle 22 1 Introduction 24 Stringent safety requirements over a wide range of operational conditions are applied to modern high speed trains. 25 An understanding of the aerodynamic forces acting on a vehicle is mandatory, especially under crosswind con-26 ditions, in order to construct useful operational safety constraints. The measurement of force coefficients for 27 full-scale vehicles is optimal but expensive, and normal practices are geared towards the use of small-scale mod-28 els that can be tested inexpensively in wind tunnel experiments or by using full-scale-in-service vehicles (Baker, 29 2010). However experimental methods are limited in scope with respect to the study of such questions as the 30 optimization of vehicle shape over a range of design parameters. In comparison, computational methods have the 31 potential to provide detailed flow information at a cost that is comparatively inexpensive over a much wider range 32 of operational conditions. For example these methods can be used to determine optimal shape forms in terms of 33 stability and drag constraints. 35The use of computational methods to assess the aerodynamic loading on trains has been recognized by the transport 36 industry. For example the German standard EN 14067-6 (DB Netz AG, 2010) permits evaluation of aerodynamic 37 forces by means of computational fluid dynamics (CFD) simulations for full-scale or reduced model geometries. 38The guidelines for CFD in EN 14067-6 using RANS (Reynolds-averaged Navier-Stokes) equations are stringent 39 and give a specific error criterion that CFD calculations must satisfy. In particular the standard requires that com-40 puted integral forces cannot be accepted for certification work if variations against accepted reference values (i.e. 41 experiment) differ by more than three percent. A major challenge in satisfying EN 14067-6 requirements is due 42 to the multi-scale nature of the flow problem which is characterized by a large ra...
In firearm examiners' and forensic specialists' casework as well as in air gun proof testing, reliable measurement of the weapon's muzzle velocity is indispensable. While there are standardized and generally accepted procedures for testing the performance of air guns, the method of seating the diabolo pellets deeper into the breech of break barrel spring-piston air guns has not found its way into standardized test procedures. The influence of pellet seating on the external ballistic parameters was investigated using ten different break barrel spring-piston air guns. Test shots were performed with the diabolo pellets seated 2 mm deeper into the breech using a pellet seater. The results were then compared to reference shots with conventionally loaded diabolo pellets. Projectile velocity was measured with a high-precision redundant ballistic speed measurement system. In eight out of ten weapons, the muzzle energy increased significantly when the pellet seater was used. The average increase in kinetic energy was 31 % (range 9-96 %). To conclude, seating the pellet even slightly deeper into the breech of spring-piston air guns might significantly alter the muzzle energy. Therefore, it is strongly recommended that this effect is taken into account when accurate and reliable measurements of air gun muzzle velocity are necessary.
Amongst hundreds of different projectiles for air guns available on the market, hollow-point air gun pellets are of special interest. These pellets are characterized by a tip or a hollowed-out shape in their tip which, when fired, makes the projectiles expand to an increased diameter upon entering the target medium. This results in an increase in release of energy which, in turn, has the potential to cause more serious injuries than non-hollow-point projectiles. To the best of the authors' knowledge, reliable data on the terminal ballistic features of hollow-point air gun projectiles compared to standard diabolo pellets have not yet been published in the forensic literature. The terminal ballistic performance (energy-dependent expansion and penetration) of four different types of .177 caliber hollow-point pellets discharged at kinetic energy levels from approximately 3 J up to 30 J into water, ordnance gelatin, and ordnance gelatin covered with natural chamois as a skin simulant was the subject of this investigation. Energy-dependent expansion of the tested hollow-point pellets was observed after being shot into all investigated target media. While some hollow-point pellets require a minimum kinetic energy of approximately 10 J for sufficient expansion, there are also hollow-point pellets which expand at kinetic energy levels of less than 5 J. The ratio of expansion (RE, calculated by the cross-sectional area (A) after impact divided by the cross-sectional area (A ) of the undeformed pellet) of hollow-point air gun pellets reached values up of to 2.2. The extent of expansion relates to the kinetic energy of the projectile with a peak for pellet expansion at the 15 to 20 J range. To conclude, this work demonstrates that the hollow-point principle, i.e., the design-related enlargement of the projectiles' frontal area upon impact into a medium, does work in air guns as claimed by the manufacturers.
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