Quantification of forces required for stabbing with screwdrivers and other blunter instruments

Parmar, Kiran<sup>1</sup>; Hainsworth, Sarah Victoria<sup>2</sup>; Rutty, Guy Nathan<sup>1</sup>

Affiliations

¹East Midlands Forensic Pathology Unit, University of Leicester, Robert Kilpatrick Building, Leicester Royal Infirmary, Leicester, UK

²Department of Engineering, University of Leicester, Leicester, UK

Abstract and keywords

In the UK, stabbing is the most common cause of homicide. The weapons used include knives, swords, screwdrivers and glass shards. Quantifying the exact force used in a stabbing incident is considered to be a difficult area due to the large number of variables present, such as sharpness of weapon, angle of attack and relative movements of the people involved. Having quantifiable data would allow a forensic pathologist to make a more informed decision when it comes to answering the commonly posed question in court “what was the degree of force involved in the stabbing incident?” The answer to this question is considered significant in determining an alleged assailant’s intent to cause harm. This paper presents results of the first detailed study relating geometry of screwdrivers to the forces required for penetration. Additionally, a range of other blunt weapons such as pens and chisels have also been studied. A silicone rubber–foam analogue has been used as the main skin simulant owing to it having similar mechanical properties to that of human skin and giving highly repeatable results. Different screwdrivers of varying shape and size have been tested (i.e. slotted, Phillips, posidriv and Torx), along with other implements including chisels and pens. The weapon geometry was characterised and related to the peak force required for penetration. Our results show that there is a direct correlation between the cross-sectional area of a screwdriver head and the amount of force required for penetration. Screwdrivers with larger cross-sectional areas require a significantly greater force to penetrate (forces in the region of 100–120 N) but “sharper” slotted screwdrivers penetrate with much lower forces (∼30 N). The forces required for penetrating the rubber–foam analogue with screwdrivers are higher than for “sharp” knives, but in some cases similar to the forces required for stabbing with “blunt” knives. For the other weapons such as chisels and biros, the force required for penetration was again high and there was found to be a good relationship between area of the implement making contact and penetration force.

Keywords: Forensic; Stab; Forc;e Screwdriver; Attack; Penetration

Links

DOI: 10.1007/s00414-011-0562-9

PubMed: 21465182

WoS: 000299091400007

History

Received: 2010-08-04

Accepted: 2011-03-03

Online: 2011-04-05

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Cited By (8)

Year	Entry
2016	Bolliger SA, Kneubuehl BP, Thali MJ, Eggert S, Siegenthaler L. Stabbing energy and force required for pocket-knives to pierce ribs. Forensic Sci Med Pathol. December 2016;12(4):394-398.
2013	Hainsworth SV. How much force? In: Rutty GN, ed. Essentials of Autopsy Practice: Innovations, Updates and Advances in Practice. London: Springer-Verlag; 2013:151-170.
2013	Ní Annaidh A, Cassidy M, Curtis M, Destrade M, Gilchrist MD. A combined experimental and numerical study of stab-penetration forces. Forensic Sci Int. December 10, 2013;233(1-3):7-13.
2017	Benson N, Dos Santos RO, Griffiths K, Cole N, Doble P, Roux C, Blanes L. The development of a stabbing machine for forensic textile damage analysis. Forensic Sci Int. April 2017;273:132-139.
2018	Komo L, Grassberger M. Experimental sharp force injuries to ribs: multimodal morphological and geometric morphometric analyses using micro-CT, macro photography and SEM. Forensic Sci Int. July 2018;288:189-200.
2020	Dempsey N, Blau S. Evaluating the evidentiary value of the analysis of skeletal trauma in forensic research: a review of research and practice. Forensic Sci Int. February 2020;307:110140.
2020	Sloan K, Robertson J, Fergusson M, Spratford W. An evaluation of human stabbing performance to inform the standardisation of textile damage examinations: do simulation trials correlate to reported stabbings? Forensic Sci Int. July 2020;312:110305.
2023	Heckmann V, Engum V, Simon G, Poór VS, Tóth D, Molnar TF. Piercing the surface: a mechanical analysis of stabbing with household tools. J Forensic Sci. July 2023;68(4):1218-1227.