Defence Science Technology Laboratory
Imagine breaking away from the traditional picture of slow moving heavy tracked armoured vehicles to lighter, faster, more agile and highly fuel-efficient platforms; designed to operate at very high tempo, well within the enemys decision cycle and with increased survivability through agility, terrain access and tactical manoeuvrability.
This is the vision being realised as part of the Defence Science and Technology Laboratory (Dstl) and its Mounted Combat Systems research project. A key component of that research has been joint activity between Dstl and global integrated defence and security company, QinetiQ.
Focused on research and risk reduction, the programme aims to significantly enhance the mobility of wheeled military vehicles through the introduction of a number of innovative technologies and design approaches.
Future armoured vehicles will need to operate at a much higher tempo if they are to be effective and survivable on the future battlefield, characterised by deep effects and short sensor to shooter links.
In this context the advantages of wheeled vehicles over tracks are well known; they provide improved ride, higher speeds, higher reliability and fuel efficiency; however traditionally they have lacked the terrain accessibility of tracked platforms which constrains freedom of movement.
One of the key technologies that enables this approach is electric drive. Dstl and QinetiQ are harnessing this capability, taking advantage of the flexibility it can provide to develop high performance active suspension solutions, which not only have long travel and variable ride height but a geometry that allows the wheel base and track to be altered.
In addition, the exploitation of individual wheel torque control provided by QinetiQs hub drive technology and all wheel steering strategies further enhance stability and off road performance. The resulting technology solutions can provide vehicles with some enhanced and even unique capabilities, including:
- provision of a compact configuration for transportation or operation in urban areas
- good stability at high speeds or on side slopes
- enhanced step climbing
- enhanced gap crossing
- improved soft soil mobility, especially when operating in convoys
- stable and low vibration crew and weapon platform
- ride height that can be optimised for low silhouette or mine stand-off
To demonstrate the potential functionality and capability of novel mobility solutions, Dstl and QinetiQ have built and are progressively upgrading a 1/3 scale 8x8 demonstrator platform called the Mobility Test Rig (MTR).
The aims of building the rig have been to address the key challenges of suspension and drive control software, sensor performance and maximising off road performance.
The MTR in its current build standard will be on display at QinetiQs stand at industry trade show, DSEi (stand H7 510). It has fully articulating suspension, QinetiQ electric drive, advanced multi-wheel steer and wheel traction control. Following this showcase, the final stage of fitting sensors and implementing the full active suspension capability will take place.
The MTR has been presented to the British Army and the significant impact on the capability of future land platforms is recognised.
Plans are being discussed to fully exploit the potential of the technology for near term platforms and in the longer for concepts that are starting to be explored as part of Project Mercury.
Mike Sewart, CTO at QinetiQ, explains:
We have been highlighting the importance of Mission-Led Innovation and this is a perfect example of that approach in practice.
Two years ago we announced this joint research programme. Through a highly focussed programme of innovation, implemented with a clear outcome in mind, in just 24 months we have, alongside a strong ecosystem of partners, designed this demonstrator to showcase how electric drive is a key enabler for future armoured wheeled vehicle success in land environments.
William Suttie, the Dstl technical lead said,
This project is not just about improving the off road mobility of wheeled platforms but has the potential to transform how future armoured vehicles are designed and used.
The ability to move quickly and safely across all types of terrain and provide a stable platform so the crew can operate effectively on the move will enhance tempo and operational freedoms and contribute significantly