To assist States with the implementation of Article 9 and Part 3 of the Technical Annex, in 2009 the then Coordinator on Generic Preventive Measures, Colonel Jean-Christophe Le Roux of France, developed a questionnaire which serves as a checklist for States to consider when they are developing procedures, guidelines or regulations on the implementation of generic preventive measures. The checklist has been reproduced in full below. It can also be found in Protocol V document CCW/P.V/CONF/2010/6/Add.1, 11 November 2010. Essentially the checklist is a tool to facilitate the implementation of generic preventive measures. While it does not have any legal status, it is hoped that the checklist will clarify various issues, establish best practises and serve to monitor and improve the implementation of generic preventive measures at the national level.
(a) Has each stage (storage, transport, handling, training, use, …) of the life cycle of munitions been defined, in terms of
(i) Normal conditions, abnormal conditions and accidental conditions of use
(b) Are quantitative reliability and safety requirements included in the specification for the entire life cycle?
(c) Is there a maximum allowable UXO rate?
(d) Have the types of targets to be engaged and scenarios of use by munitions been considered and characterized?
(e) Are the impact conditions of the munitions considered i.e. angle of impact of munitions/ type of impact surface?
(f) Has fuse sensitivity been defined in specification?
(g) Are any materials, which are forbidden by international standards or regulations, used?
(h) Which design standards shall be applied during development and production? Are they internationally recognized? If not, is there a comparison matrix between standards?
(a) Does the design work include features and parameters to enable munitions products to meet the specified requirements for reliability, safety, storage, transport and handling, throughout the whole life cycle of munitions (e.g. : including operational usage and disposal)?
(b) Are munitions designed to maintain the required level of reliability in all specified environmental and foreseeable operational conditions throughout all life cycle stages?
(c) Is the quality of the chosen components (materials, mechanical parts, explosive materials, compatibility and time degradation of pyrotechnic materials, electronic parts, battery…) optimised against the performance and the specified UXO rate?
(d) Where appropriate and technically feasible, does the design permit the testing of critical functions, which may lead to UXO prior to use (by user or BIT)?
(e) Does the fusing system incorporate design features, which definitively limit the foreseen active time of munitions: self-destruction mechanism, self-deactivating feature (e.g. Electrical Firing Energy Dissipation), self-neutralisation mechanism (e.g. disarming, sterilisation), and self-disruption?
(f) Are features or functions, related with safety, tested at a 100% level?
(g) Does the design of the fusing system include features that facilitate, as applicable, effective automated and/or manual quality assurance methods, tests and inspections?
(h) Are munitions designed to achieve the specified lifetime without unacceptable degradation of reliability and safety?
(i) Does the design of munitions include features for health monitoring that facilitate, as applicable, a prognostics and diagnostics capability, thereby assuring the effectiveness and reliability of munitions throughout the lifecycle?
(j) Are the lot numbers marked on munitions?
(k) Has a reliability and safety analysis been performed e.g. are potential malfunctions of munitions analysed and is the design improved and verified by analysis and specific reliability and safety tests?
(l) Are critical functions and characteristics, with respect to UXO, defined?
(m) Are quantitative reliability and safety requirements assessed by analysis and tests?
(n) If, in munitions, there are software or programmable components, do you refer to international standards? Do you define, plan and perform specific activities to assure reliability and safety?
(o) Has process analysis been realised to assure the greatest reliability of munitions? (e.g. FMECA process)
Reducing UXO sensitivity
Reducing potential civilian casualties from ERW
5. Utilisation - 5.1 Storage
5.2 Transportation and handling
6. Support - 6.1 maintenance of weapon system, munitions and packaging
6.2 In service surveillance
7. Disposal Identification
Information to other parties
8. COTS and MOTS
9. Others questions for storage related to safety
List of abbreviations
(ii) Type of environmental conditions and the level to which munitions may be exposed (direct or indirect exposure i.e when integrated in weapon system),
(iii) Duration of exposure to different environmental conditions,
(iv) Configuration/ state of munitions during periods of exposure to different environmental conditions,
(v) Maximum allowable degradation during its operational lifecycle i.e. during storage, transport, handling, use with particular weapons systems …?
(vi) Is there a requirement for a specified life time?
ALARP: As Low As is Reasonably Practicable
AXO: Abandoned explosive Ordnance
BIT: Built In Test
CCW: Certain Conventional Weapons
COTS: Commercial Off The Shelf
EOD: Explosive Ordnance Disposal
ERW: Explosive Remnants of War (see definition in convention on CCW)
HCP: High Contracting Party
MOTS: Modified Off The Shelf
RFID: Radio Frequency Identification Device
UXO: Unexploded Ordnance (see definition in convention on CCW)