Leopard 2 Armored Engineer Vehicles replace Leo-1 Badgers in Canadian army


As part of the Force Mobility Enhancement (FME) project, the Canadian army began receiving 18 new and improved Leopard 2 Armored Engineer Vehicles (Leo 2 AEVs) in late fall 2017 to provide critical support to the Canadian army’s Leopard 2A4 main battle tanks, Light Armored Vehicles, Tactical Armored Patrol Vehicles and future fleets.


Leopard 2 Armored Engineer Vehicles replace Leo 1 Badgers in Canadian army 

Leopard 2 AEV replaces CA’s aging Leopard 1-based Badger AEV (Picture source: Canadian Army)


The delivery of these vehicles also helps support the long-term investment in the Canadian Army that is outlined in Strong, Secure, Engaged: Canada’s Defence Policy to enhance capabilities and capacities in heavy engineering equipment for use in operations and at home, including in the North.

The Leo 2 AEV is a heavily protected and mobile vehicle complete with a range of engineering tools. It is used in overseas operations for general debris clearing, mine-clearing, excavating and rescue operations and can be used at home for domestic disaster relief efforts for events such as floods or fires. This versatile vehicle carries three personnel, can reach road speeds of about 60 km/h, has additional add-on armour and its combat-ready weight is 69,500 kg. It is also capable of being used in Arctic conditions.

The Leo 2 AEV replaces the Canadian army’s aging Leopard 1-based Badger AEV (Bergpanzer in the German and Belgian armies). It is a product of Germany’s Flensburger Fahrzeugbau Gesellschaft (FFG) mbH, which has a subsidiary in Bathurst, New Brunswick where most of the work on the Leo 2 AEV project is being conducted. Improvements to the Leo 2 AEV include better armor to protect operators under fire on the battlefield, a remote weapons system, with a C6 7.62-mm medium machine gun and a 76-mm multi-barrel grenade dispenser. It also has upgraded welding and cutting equipment, a mine breaching system and the so-called "jaws of life," a type of hydraulic tool used in emergency rescues to extract trapped victims from severely damaged vehicles. The main winch has a 40,000-kg pull, and the auxiliary winch has a 3,500-kg pull. It is equipped with a variety of imaging equipment, including thermal-imaging cameras, which allows it to be used during the day, at night and in bad visibility conditions.

All this is in addition to existing capabilities, including a bulldozer blade used to clear rubble and level surfaces, an excavator bucket to move hundreds of cubic meters of earth and debris per hour, an excavator arm with interchangeable attachments used to lift large objects upwards of 4,000 kg, and a capstan winch (a rotary hydraulic device for pulling or hoisting) capable of handling huge loads. AEVs are also used to fill in craters and perform limited road maintenance and construction jobs.

The Leo 2 AEVs, which are expected to support the Leopard 2A4 main battle tanks until 2035, will further enhance the Canadian army's mobility and deployability in an ever-widening range of future missions. "It is the natural evolution," said AEV Project Director, Major Richard Toppa. "We've basically kept the same capabilities, but we've upgraded. The dozing rate is far greater than that of the old Badger and the digging rate with the excavator is also far greater. As technology and vehicle horsepower change, we increase our capabilities."

Members of Edmonton-based 1st Combat Engineer Regiment (1 CER) received the first six AEVs and completed initial training (ICT) late in 2017, giving the CA a foundation of fully-qualified soldiers capable of operating and maintaining the new fleet, and training others to do so. "The Leo 2 has a specifically-geared transmission and set of final drives that really help us get in there and push the dirt," said Master Corporal Bobby Talaber, a Leo 2 Crew Commander. "We have some pretty tough conditions here with the frozen ground, but the machine is still able to power through."

Although the Leo 2 and its predecessor have many similarities, training to work on the new AEV involves becoming familiar with all of the components, hydraulic and electrical systems and schematics as well as its new features.