A systems approach to the design of personal armour for explosive ordnance disposal

Couldrick, Christopher A.

January 2004

A qualitative description of the personal armour design system is elicited by comparing armour throughout the ages. Inputs that 'shape' designs are the materials technology, threat, wearer, task and environment. The emergent properties of protection, ergonomic effectiveness and financial cost form the basis of trade-offs to select final solutions. Work on the protection subsystem refines the key positive emergent property of personal armour. Existing quantifications of protection effectiveness are rejected in favour of a novel measure named the Usefulness Factor, UF. This is the first measure that accounts for the real benefit of armour. A five-stage model is proposed for the assessment of protection. Two feedback loops - due to making tasks as safe as possible and the ergonomic penalty of armour are evident. These must be considered in order to assess protection correctly. Casualty reduction analysis software (CASPER) is used to produce 'approach plots' and 'zones of usefulness' in order to make tasks safer and map the benefit of armour. This approach is demonstrated with the UK's Lightweight Combat EOD Suit against L2A2 and No. 36 Mills grenades, an HB876 area denial mine, a BL 755 sub-munition and a 105mm artillery shell. Assessment of secondary fragmentation from antipersonnel (AP) blast mines defines a threat input that is specific to Explosive Ordnance Disposal (EOD). Trials are carried out with explosive charges of 50g to 500g, buried under 5 or 10cm of stones and sand at a range of 1m. The threat is defined in terms of the probabilities of (a) being hit, (b) a hit perforating armour and (c) a hit incapacitating an unarmoured person. The chances of being hit close to the ground decrease to approximately 15% of the value when directly above the mine. Secondary fragmentation is not likely to perforate armour that protects against primary fragments. However, it is likely to incapacitate an unarmoured person. Protection is traded-off against proxies for ergonomic and financial cost effectiveness by using quantitative optimisation of personal armour. This introduces the concept of a 'protection optimisation envelope', which defines the bounds of possibility rather than a single solution. CASPER is adapted to produce weight and cost as well as incapacitation parameters. This provides a model that generates both benefits and constraints of armour. Hence, the foundations are laid for the world's first fully integrated personal armour design tools. The ergonomic effectiveness subsystem is the primary constraint of personal armour. Visor demisting for the UK's Mk 5 EOD Suit provides a simple example. Existing methods of assessment of the ergonomic penalty of armour are considered. A novel development of biomechanics computational models is proposed to predict both the mechanical and thermal burdens of armour.

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A systems approach to the design of personal armour for explosive ordnance disposal

Couldrick, C A

11 1900

A qualitative description of the personal armour design system is elicited by comparing armour throughout the ages. Inputs that 'shape' designs are the materials technology, threat, wearer, task and environment. The emergent properties of protection, ergonomic effectiveness and financial cost form the basis of trade-offs to select final solutions. Work on the protection subsystem refines the key positive emergent property of personal armour. Existing quantifications of protection effectiveness are rejected in favour of a novel measure named the Usefulness Factor, UF. This is the first measure that accounts for the real benefit of armour. A five-stage model is proposed for the assessment of protection. Two feedback loops - due to making tasks as safe as possible and the ergonomic penalty of armour are evident. These must be considered in order to assess protection correctly. Casualty reduction analysis software (CASPER) is used to produce 'approach plots' and 'zones of usefulness' in order to make tasks safer and map the benefit of armour. This approach is demonstrated with the UK's Lightweight Combat EOD Suit against L2A2 and No. 36 Mills grenades, an HB876 area denial mine, a BL 755 sub-munition and a 105mm artillery shell. Assessment of secondary fragmentation from antipersonnel (AP) blast mines defines a threat input that is specific to Explosive Ordnance Disposal (EOD). Trials are carried out with explosive charges of 50g to 500g, buried under 5 or 10cm of stones and sand at a range of 1m. The threat is defined in terms of the probabilities of (a) being hit, (b) a hit perforating armour and (c) a hit incapacitating an unarmoured person. The chances of being hit close to the ground decrease to approximately 15% of the value when directly above the mine. Secondary fragmentation is not likely to perforate armour that protects against primary fragments. However, it is likely to incapacitate an unarmoured person. Protection is traded-off against proxies for ergonomic and financial cost effectiveness by using quantitative optimisation of personal armour. This introduces the concept of a 'protection optimisation envelope', which defines the bounds of possibility rather than a single solution. CASPER is adapted to produce weight and cost as well as incapacitation parameters. This provides a model that generates both benefits and constraints of armour. Hence, the foundations are laid for the world's first fully integrated personal armour design tools. The ergonomic effectiveness subsystem is the primary constraint of personal armour. Visor demisting for the UK's Mk 5 EOD Suit provides a simple example. Existing methods of assessment of the ergonomic penalty of armour are considered. A novel development of biomechanics computational models is proposed to predict both the mechanical and thermal burdens of armour.

Body armour

Casualty reduction analysis

Ergonomics

Explosive ordnance disposal

Optimisation

Personal armour

Protection

Secondary fragmentation

Systems approach

Usefulness factor

<b>Sea-Based Disaster Response Logistics</b>

Paul L Knudsen (18933415)

03 July 2024

<p dir="ltr">The purpose of this study is to develop the attributes of an undersea aid cache network and validate its efficacy in reducing the number of dead and injured in island natural disasters. This study addresses the problem of island nations experiencing three times the dead and injured as continental nations during natural disasters due to easily disrupted and limited logistics. Employing a mixed-method approach, the qualitative portions of the study include a systematic literature review and case study analysis. The quantitative portions of the study include populating a novel disaster database, applying statistical analysis, executing a suitability assessment, and running design efficacy experiments using a simulation model representative of the disaster database. The study concludes with a review of existing patents to identify an optimal combination of designs for the caches and specify research foci for further investment.</p><p dir="ltr">Despite a comparative advantage in sea assets, the findings show that islands overly rely on air resupply and underuse sea-based pre-positioned stocks. The study also finds that a network of Undersea Aid Modules (UAMs) could reduce casualties in isolated island areas if fielded in sufficient quantities and capable of longevity, survivability, and recovery. Lastly, the study reviews existing patents for UAM design requirements and highlights gaps for investment. A key research limitation is that the study does not develop a prototype and simulations cannot replicate full, real-world application. Practical implications include a novel alternative to current resupply methods and identified gaps for further study. The paper’s value and originality center on an island-unique analysis of disaster logistics absent in most studies. The study will reveal previously unidentified gaps and a design solution to improve island disaster outcomes.</p><p dir="ltr"><i>Keywords:</i> Disaster logistics, cache, pre-positioned stocks, sea-basing, island, casualty reduction</p>

Transport planning

Marine engineering

Naval architecture

Disaster logistics

cache

aid

pre-positioned stocks

sea-basing

island

casualty-reduction