Handling lift trucks batteries can be one of the most important day-to-day tasks in warehouses and factories. Ensuring these routine procedures are carried out quickly, efficiently and above all safely is essential to avoid manual handling injuries.
Sooner or later a lift truck battery must be recharged. Charging in-situ can take too long in intensive applications and the only way to keep trucks running productively is to replace a depleted battery with a fully charged unit and recharge the original in a charging rack.
In the past, batteries were lifted in and out by hand or with some kind of crane. Another way was to pull the battery off the truck by hand and push the replacement back in. Neither process is ideal and, as with any manual handling of large items, there was always a risk of accident or injury. Dropping batteries during a change can also lead to an acid spill that will need containment, as well as damage to batteries, floors and related equipment.
Precise information about accidents and injuries related to battery handling is not readily available. Official sources, such as the HSE’s RIDDOR, do not break the data into sufficient detail. Nevertheless the decline in overall accident and injury rates in recent years suggests improvements across all parts of industry.
Progress in truck and battery design means there is no longer any need for manual lifting and handling. Most lift trucks now incorporate a battery compartment with side access and rollers in the floor, while charging facilities have battery beds at the same height. The truck drives alongside a charging position, the depleted battery is rolled out and a fully charged replacement rolled back in.
For larger vehicles with heavier and bigger batteries, the truck can incorporate mechanical assistance such as a magnetic arm to move the battery into position. A cart, ideally a specially designed battery change cart which typically also incorporates powered rollers and magnetic arms, can be used to transfer the battery if the truck cannot approach the charging station.
The move away from manual handling to semi- or fully-automated battery handling systems was driven by increasingly stringent manual handling regulations. These, and other health and safety legislation, have forced operators to reassess their operations. In particular, the manual handling regulations called for operators to remove manual handling processes wherever possible. Although it is not mandatory to provide battery handling equipment to comply with current legislation, progressive operators recognise the resulting safety, reliability and performance benefits that often make the investment worthwhile.
Many operators now choose to install dedicated areas where batteries can be charged and changed safely. These are ideally designed with a compact layout, efficient truck movement pathways, and safe parking zones. Tasks such as battery and charger management, battery changing and battery service should ideally be managed by dedicated operatives. If this proves impractical, then fully-trained experienced drivers can carry out many of these functions while still significantly reducing any potential risks and hazards. Safety barriers can be installed to restrict access to non-authorised personnel and vehicles.
Good planning minimises truck movements and the time spent in charging areas, which is safer for operators, pedestrians and bystanders. Ideally the charging stations are arranged along aisles with the outer face towards the truck operating area. The inner face is configured for pedestrian access, which removes potential points of contact between moving trucks and staff responsible for managing the installation so routine checks and maintenance can be carried out safely. Whatever system is used the installation of equipment is important. Safe routing of DC cables on the chargers and the batteries will avoid damage and stop them becoming a trip hazard.
Another safety consideration is the small risk of arcing during disconnection or connection when changing batteries. The latest-generation chargers incorporate circuitry and features including ‘Late Make, Early Break’ plugs to minimise this risk. Ventilation systems remove gases, but these can be uneconomic in smaller warehouses or when charging stations are dispersed throughout larger sites. Batteries with ‘low gassing’ are an ideal alternative.
The standard covering battery rooms and charging is EN50272. This is used as a reference by leading battery and truck manufacturers. Batteries themselves are considered ‘articles’ under REACH regulation 1907/2006/EC, which means they do not require a published safety data sheet. Manufacturers are, however, required to provide safety information on products in an MSDS document. This covers the safe use of batteries with details about composition, the electrolytes, potential hazards, transportation, end-of-life disposal and more. The resulting benefits of automatising handling of lift truck batteries and stricter manual handling regulations have brought safety improvements across the industry.
John Lawton is director of marketing for EnerSys Motive Power, Europe, Middle East & Africa
By British Safety Council on 03 December 2018
The British Safety Council has revealed the winners of its multimedia poster competition, ‘Images of wellbeing’, which showcases images of wellbeing at work and in an educational environment.
By Mark Glover explores the music sector‘s health and safety responsibilities on 03 September 2018
A former member of the Royal Opera House orchestra has won a case against his ex-employers for hearing damage. Will the ruling – the first of its kind – be the catalyst for similar claims and does the entertainment and industry now need to sit up and take notice?
By Estelle Clark, Chartered Quality Institute looks at changes ushered in by ISO 45001 on 01 August 2018
The publication of ISO 45001 is a right step in addressing safety on a global scale. Organisations must guarantee similar occupational standards in their supply chains.