Determination of the Shot Energy Characteristics of the Pneumatic Gun by Means of High Speed Imaging Method

Wojciech Jóźwik; Andrzej Zbrowski

doi:10.4028/www.scientific.net/SSP.199.291

Paper Titles

Application of Hybrid Vision Method for the Hot Aluminium Surface Inspection
p.267

Application of the 'Iterative Closest Point' Algorithm for Determination of Rotation Axis of a Turntable
p.273

Control Curves Method of Airframe Geometry Modeling
p.279

Detection of Cesium from Pollucite Using Laser-Induced Breakdown Spectroscopy
p.285

Determination of the Shot Energy Characteristics of the Pneumatic Gun by Means of High Speed Imaging Method
p.291

Effect of Cross Section Size on Ductility and Fragmentation of Copper Ring at High Strain Rate Loading Conditions
p.297

Experimental Shear Stress Analysis of the Thin Walled Aluminum Hollow Shaft under Torsion
p.303

Force Sensor for Laparoscopic Tool of RobIn Heart Robot
p.309

Influence of CNC Machine Tool Technical Condition on the Geometrical Accuracy of Freeform Surfaces
p.315

HomeSolid State PhenomenaSolid State Phenomena Vol. 199Determination of the Shot Energy Characteristics...

Determination of the Shot Energy Characteristics of the Pneumatic Gun by Means of High Speed Imaging Method

Abstract:

The article presents the method for the determination of energy characteristics of the pneumatic cannon by means of high speed imaging. The gun tested is a device enabling bird collision endurance tests to be conducted for the structural element of aircrafts. In the tested 250 [m system, the projectiles were thrown in the plastic sabot damaged in the muzzle of the gun. The tests were conducted in the speed ranging between 100 300 m/s for 0.9 and 3.6 [k projectiles. The objective of the tests was to determine the characteristics of the projectile outlet velocity in the feed pressure function. The measurement stand was equipped with the Phantom V310 high speed camera The speed measurement was conducted with the use of the digital image analysis in which commercial TEMA Motion software was used. Results were corrected so that the parallax error could be eliminated. Because of the cylindrical shape of the projectile, the parallax error for the front at the back of the projectile varied, which required two correction coefficients to be applied. The speed was calculated by the averaging of the results for the front and the back of the projectile. For the recordings, in which the remaining of the sabot prevented the accurate arrangement of measurement points, a simplified speed measurement method was used. Measurement uncertainty sources are also described (shift of the projectile at the time of the exposure, measurement point positioning error). The influence of the parallax error on the measurement result and the cannon energy characteristics obtained are presented. The obtained characteristics enable proper selection of feed pressure allowing for the procurement of the outlet velocity suitable for the tests conducted.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Solid State Phenomena (Volume 199)

Pages:

291-296

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.199.291

Citation:

Cite this paper

Online since:

March 2013

Authors:

Wojciech Jóźwik, Andrzej Zbrowski

Keywords:

Energy Characteristics, High Speed Camera, Mage Analysis, Pneumatic Gun, Speed Determination

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] A. Zbrowski, The testing of the prototype of the pneumatic gun, Maintenance Problems. 82 (3) (2011) 217-232. (in polish).

Google Scholar

[2] L.C. Ubels, A.F. Johnson, J.P. Gallard and M. Sunaric, Design and testing of a composite bird strike resistant leading edge, The SAMPE Europe Conference & Exhibition, Paris, France, 1-3 April (2003).

Google Scholar

[3] J. Sánchez-Pena, C. Marcos, M. Fernández, Cost-effective optoelectronic system to measure the projectile velocity in high-velocity impact testing of aircraft and spacecraft structural elements, Optical Engineering. 46 (5), (2007).

DOI: 10.1117/1.2740771

Google Scholar

[4] C-H. Tho, M. R. Smith, Accurate bird strike simulation methodology for ba609 tiltrotor, The Journal of the American Helicopter Society, 56 (2011) 8.

DOI: 10.4050/jahs.56.012007

Google Scholar

[5] G. Socha, S. Szałkowski, A. Zbrowski, Nowy system do badania odporności na zderzenie elementów konstrukcji samolotów i pojazdów lądowych zainstalowany w Instytucie Lotnictwa, XVIII Seminarium NIENISZCZĄCE BADANIA MATERIAŁÓW, Zakopane , Poland, 13-16 March 2012, 7-17. (in polish).

Google Scholar

[6] I. Kirschner, Results of Selected Experiments Involving Supercavitating Flows, RTO AVT/VKI special course: supercavitating flows, von Karman Institute for Fluid Dynamics, Rhode-Saint-Genese, Belgium, 12-16 February (2001).

Google Scholar

[7] J. Sánchez-Pena, C. Marcos, A. Carrasco, Development of Optoelectronic Sensor and Transceivers for Spacecraft Applications, in: J. Hall, Advanced in Spacecraft Technologies, InTech, 2011, pp.99-122.

DOI: 10.5772/13807

Google Scholar

[8] J. Dean, C. Dunleavy, P. Brown, T. Clyne, Energy absorbtion during projectile performation of thin steel plates and the kinetic energy of ejected fragments, International Journal of Impact Engineering. 36 (10-11) (2009) 1210-1222.

DOI: 10.1016/j.ijimpeng.2009.05.002

Google Scholar

[9] A. Richards, Applications for High-Speed Infrared Imaging, 26th International Congress on High-Speed Photography and Photonics, 17 March (2005).

DOI: 10.1117/12.581293

Google Scholar

[10] P. Hazell, G. Kister, C. Stennett, P. Bourque, G. Cooper, Normal and oblique penetration of woven CFRP laminates by a high velocity steel sphere, Composites Part A: Applied Science and Manufacturing. 39 (5), (2008) 866-874.

DOI: 10.1016/j.compositesa.2008.01.007

Google Scholar

[11] P. Hazell, G. Kister, C. Stennett, P. Bourque, G. Cooper, Normal and oblique penetration of woven CFRP laminates by a high velocity steel sphere, Composites Part A: Applied Science and Manufacturing. 39 (5), (2008) 866-874.

DOI: 10.1016/j.compositesa.2008.01.007

Google Scholar

[12] P. Forest, D. Crim; K. Martir, P. Pizzola, Gunshot Residue Particle Velocity and Deceleration, Journal of Forensic Sciences. 49 (6), (2004).

DOI: 10.1520/jfs2003137

Google Scholar