Top

Experimental Mechanics

Published in:

01-04-2014

Small Scale Models Subjected to Buried Blast Loading Part I: Floorboard Accelerations and Related Passenger Injury Metrics with Protective Hulls

Authors: Xing Zhao, Gary Shultis, Ryan Hurley, Michael Sutton, William Fourney, Uli Leiste, Xiaomin Deng

Published in: Experimental Mechanics | Issue 4/2014

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Small scale models representing key vehicle structural elements, including both floorboards and bottom-mounted, downward V-shape hulls in various configurations, have been manufactured and subjected to a range of buried blast loading conditions. By varying surface stand-off distance and depth of burial for several hull and structure configurations, the input-scaled response of aluminum full-scale vehicle floorboards has been quantified using high speed stereo-vision. Specifically, the maximum vertical acceleration on the floorboard and the corresponding Head Injury Criterion (HIC₁₅) are quantified as metrics to assess the severity of the blast event. Results show standard V-shaped hulls provide essential blast mitigation, with reductions in floorboard measurements up to 47X in maximum acceleration and HIC₁₅. Though variations in protective hull geometry provide modest reductions in the severity of a floorboard blast event, results also show that personnel on typical floorboard structures during blast loading events will incur unacceptable shock loading conditions, resulting in either serious or fatal injury. A more appropriate design scenario would be to consider situations that employ frame-mounted passenger seating to reduce the potential for injury. A second set of experiments will be presented in Part II that focuses on frame motions and accelerations when steel frames and steel structures are employed with various frame connections and coatings for frame blast mitigation.

previous article Understanding the Dynamic Behaviour of a Tennis Racket under Play Conditions

next article Quantification of Three-Dimensional Surface Deformation using Global Digital Image Correlation

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Available only for authorised users

Review of video data indicates that each plate-frame structure moves upward rigidly, with minimal rotation, during the first 36 ms after initial detonation. This was true for all experiments performed in this study.

Head H (1920) The sense of stability and balance in the Air. The Medical Problems of Flying, Oxford

Brown JL, Lechner M (1956) Acceleration and human performance; a survey of research. J Aviat Med 27(1):32–49

Duane T (1953) Preliminary Investigation into the Study of the Fundus Oculi of Human Subjects under Positive Acceleration. (Report No. NADC-MA-5303). Naval Air Development Center, Johnsville, PA

Stoll A (1956) Human tolerance to positive G as determined by the physiological End points. J Aviat Med 27(4):356–67MathSciNet

Eiband M (1959) Human tolerance to rapidly applied accelerations: a summary of the literature. Lewis Research Center, Cleveland, OH

Gurdjian ES, Lissner HR, Latimer FR, Haddad BF, Webster JE (1953) Quantitative determination of acceleration and intercranial pressure in experimental head inury. Neurology 3:417–423CrossRef

Gurdjian ES, Roberts VL, Thomas LM (1964) Tolerance curves of acceleration and intercranial pressure and protective index in experimental head injury. J Trauma 600

Gurdjian ES, Hodgson VR, Hardy WG, Patrick LM, Lissner HR (1964) Evaluation of the Protective Characteristics of Helmets in Sports. J Trauma 4

Stech E, Payne P (1969) Dynamics of the human body (AD701383). Froster Engineering Development Corporation, Englewood CO

10.

Verse J (1971) A review of the Severity Index. SAE Paper 710881. Proc. 15^th Stapp Crash Conf. 771–795

11.

Goldsmith W (1979) Some aspects of head and neck injury and protection. Progress in biomechanics. Sijthoff and Noordhoff, Alphen aan den Rijn, pp 333–377

12.

Hutchinson J, Kaiser MJ, Lankarani HM (1998) The head injury crtiterion (HIC) functional[J]. Appl Math Comput 96:1–16CrossRefMATHMathSciNet

13.

Marjoux D, Baumgartner D, Deck C, Willinger R (2008) Head injury prediction capability of the HIC, HIP, SIMon and ULP criteria. Accid Anal Prev 40:1135–1148CrossRef

14.

Department of Defense (1998) Crew Systems Crash Protection Handbook (JSSG-2010-7). Washington D.C.

15.

US Army Aviation Systems Command (1989)

16.

Eppinger et al. (1999) Development of Improved Injury Criteria for the Assessment of Advanced Automotive Restraint Systems-II. NHTSA, Nov

17.

Eppinger et al. (2000) Supplement: Development of Improved Injury Criteria for the Assessment of Advanced Automotive Restraint Systems-II. NHTSA, March

18.

Nurick GN, Shave GC (1995) The deformation and tearing of thin square plates subjected to impulsive loads-an experimental study. Int J Impact Eng 18(1):99–116CrossRef

19.

Jacob N, Chung KYS, Nurick GN, Bonorchis D, Desai SA, Tait D (2004) Scaling aspect of quadrangular plates subjected to localized blast loads-experiments and prediction. Int J Impact Eng 30:1179–1208CrossRef

20.

Nurick GN, Martin JB (1989) Deformation of thin plates subjected to impulsive loading-a review. Part II: experimental studies. Int J Impact Eng 8(2):171–86CrossRef

21.

Jacob N, Nurick GN, Langdon GS (2007) The effect of stand-off distance on the failure of fully clamped circular mild steel plate subjected to blast loads. Eng Struct 29:2723–2736CrossRef

22.

Fourney WL, Leiste U, Bonenberger R, Goodings D (2005) Mechanism of loading on plates due to detonation. Fragblast Int J Blasting Fragm 9(4):205–217CrossRef

23.

Fourney WL, Leiste U, Bonenberger R, Goodings D (2006) Explosive impulse on plates. Fragblast Int J Blasting Fragm 9(1):1–17CrossRef

24.

Fourney WL, Leiste U, Taylor L (2008) Pressures acting on targets subjected to explosive loading. Fragblast Int. J. Blasting Fragm 2:167–187

25.

Shcleyer GK, Lowak MJ, Poleyn MA, Langdon GS (2007) Experimental investigation of blast wall panels under shock pressure loading. Int J Impact Eng 34:1095–1118CrossRef

26.

Lawrence RW (1944) Mechanism of detonation in explosives. J Gen Appl Geophys 9:1–18

27.

Hargather MJ, Settles GS (2007) Optical measurement and scaling of blasts from gram-range explosive charges. Shock Waves 17:215–223CrossRef

28.

Tiwari V, Sutton MA, McNeill SR, Xu SW, Deng XM (2009) Application of 3D image correlation for full-field transient plate deformation measurements during blast loading. Int J Impact Eng 36:862–874CrossRef

29.

Snyman IM (2010) Impulsive loading events and similarity scaling. Eng Struct 32:886–896CrossRef

30.

Fox DM, Huang X, Jung D, Fourney WL, Leiste U, Lee JS (2011) The Response of small scale rigid targets to shallow buried explosive detonations. Int J Impact Eng 38:882–891CrossRef

31.

Hopkinson B (1915) British Ordonance Board Minutes. 13565

32.

Cranz C, der Ballistik L (1926) Textbook of ballistics. Springer Verlag, Berlin

33.

Chabai AJ (1965) On Scaling dimensions of craters produced by buried explosives. J Geophys Res 70(20):5075–5098CrossRef

34.

Neuberger A, Peles S, Rittel D (2007) Scaling the response of circular plates subjected to large and close-range spherical explosions Part I: Air-blast loading. Int J Impact Engineering 34:859–873CrossRef

35.

Neuberger A, Peles S, Rittel D (2007) Scaling the response of circular plates subjected to large and close-range spherical explosions Part II: Buried charges. Int J Impact Engineering 34:874–882CrossRef

36.

Neuberger A, Peles S, Rittel D (2009) Springback of circular clamped armor steel plates subjected to spherical air-blast loading. Int J Impact Engineering 36:53–60CrossRef

37.

Bridgman PW (1949) Dimensional analysis. Yale University Press, New Haven, Conn

38.

Jones N (1989) Structural impact. Cambridge University Press, New York

39.

Gibbings JC (1982) Alogic of dimensional analysis. J Phys A Math Gen 15:1991–2002CrossRefMathSciNet

40.

Gibbings JC (1986) The systematic experiments. Cambridge University Press, Cambridge

41.

Genson K (2006) Vehicle shaping for mine blast damage reduction. MSc thesis, University of Maryland, USA

42.

Benedetti R (2008) Mitigation of explosive blast effects on vehicle floorboard. MSc thesis, University of Maryland, USA

43.

Fourney WL, Leiste HU, Hauck A, Jung D (2010) Distribution of Specific Impulse on Vehicles Subjected to IED’s Proceedings of SEM Fall Conference, IMPLAST 2010 held in Providence RI

Title: Small Scale Models Subjected to Buried Blast Loading Part I: Floorboard Accelerations and Related Passenger Injury Metrics with Protective Hulls
Authors: Xing Zhao
Gary Shultis
Ryan Hurley
Michael Sutton
William Fourney
Uli Leiste
Xiaomin Deng
Publication date: 01-04-2014
Publisher: Springer US
Published in: Experimental Mechanics / Issue 4/2014
Print ISSN: 0014-4851
Electronic ISSN: 1741-2765
DOI: https://doi.org/10.1007/s11340-013-9834-2

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 4/2014

Experimental Methods for Determining Residual Stresses and Strains in Various Biological Structures

Characterization of the Orthotropic Elastic Constants of a Micronic Woven Wire Mesh via Digital Image Correlation

Microscale Fracture Toughness of Bismuth Doped Copper Bicrystals Using Double Edge Notched Microtensile Tests

Dual-Configuration Fiber Bragg Grating Sensor Technique to Measure Coefficients of Thermal Expansion and Hygroscopic Swelling

Hybrid Thermoelastic Stress Analysis of a Pinned Joint

Impact Failure of Planetary Materials:

Premium Partners