The Institution is launching a new fund, Stephenson LP, aimed at helping companies overcome the investment hurdle between Research and Development and bringing a product to market.
The fund, initially worth a total of £2 million, is in line with the Institution’s original statement of purpose set out by founder George Stephenson in 1847 to “give an impulse to invention likely to be useful to the world”. It is the first investment fund of this kind by the Institution, and indeed any UK Professional Engineering Institution.
The Stephenson LP Fund is independently managed by specialist venture capital company Midven Ltd. and aims to invest in innovative companies engaged in mechanical engineering over the next few years.
The Fund’s first five investments are into blade compressor company Lontra, fuel cell catalyst developer Amalyst, sensor company Oxsensis, fusion energy company Tokamak Energy and space technology business Oxford Space Systems.
Stephen Tetlow MBE, the Institution's Chief Executive, said: “These investments by the Institution are not just about providing monetary investment, but about connecting these and other companies to the vast resources and network of the Institution and its membership.
“The Fund fulfills the Institution’s original purpose to give an impulse to invention and also help companies overcome the investment hurdle between Research and Development and bringing a product to market.
“I am really excited that through the Fund the Institution is able to support Lontra, Amalyst, Oxsensis, Tokamak Energy and Oxford Space Systems in developing exciting and innovative technologies which really are inventions likely to be useful to the world. This is the Institution getting back to its roots.”
The Institution was established in 1847 and has some of the world’s greatest engineers in its history books. It is one of the fastest growing professional engineering institutions. Headquartered in London, it has operations around the world and over 111,000 members in more than 140 countries working at the heart of the most important and dynamic industries such as the automotive, rail, aerospace, medical, power and construction industries.
Amalyst
Amalyst, based in Birmingham, is a spin-out from University College London (UCL), which has developed a class of catalyst for fuel cells (which generate electricity from hydrogen) and electrolysers (for the production of hydrogen) which are not based on platinum. The Amalyst catalyst aims to be a drop-in replacement for “gold standard” platinum catalysts but is significantly cheaper per unit of power. The progress made in the development of fuel-cell technology as well as hydrogen production has led to growing interest in the automotive sector to develop the next generation of hydrogen fuel-cell vehicles.
David Hodgson, Amalyst’s CEO, said: “We’re delighted to have the Stephenson Fund participate in this latest round of investment into Amalyst. The support of the Institution will be particularly valuable to us as we engage with multi-national companies.”
Visit the
Amalyst website.
Lontra
Lontra’s Blade Compressor® is a step change in air compressor technology, best imagined as a piston and cylinder, but with the cylinder wrapped into a ring doughnut shape. The design involves a constantly open intake port, without valves. As the piston rotates, it draws in air behind it and compresses air in front of it in an almost continuous cycle. Blade Compressor® has a unique oil-free geometry providing internal compression with very low leakage and low inlet and outlet flow losses giving a machine that is quieter, smoother and highly efficient.
A low pressure (1Bar/15psi) Blade Compressor® has already been proven in a trial with Severn Trent Water, where reductions in energy consumption of over 21% were observed. The technology is now licensed for production within the municipal and regulated waste water sector to Sulzer, a global leader in pumping equipment with 21 manufacturing facilities worldwide. The multi-million pound deal will see aeration equipment incorporating Lontra’s technology sold across 150 countries.
Steve Lindsey, CEO of Lontra, said: “We are delighted to be among the first to receive funding and endorsement from the Stephenson fund. This will support further development of our Blade Compressor® IP as we seek new licensees. We’re proud that the industrial revolution continues to this day, and that the UK remains at the forefront of engineering innovation.”
Visit the
Lontra website.
Oxford Space Systems
Harwell-based OSS launched in September 2013 to develop a new generation of deployable structures for space that are lighter, less complex and lower cost than existing products in commercial demand. Using conventional, as well as new proprietary materials, OSS is rapidly developing a range of deployable antennas, booms and panel technologies. These electro-mechanical structures are primarily focused on supporting a new generation of micro-satellites for a range of space based services.
Oxford Space Systems has secured a number of collaborative development contracts with the largest names in the European space industry and is on target to achieve in-orbit demonstration of its disruptive technology at the end of next year, setting a record in going from concept to flight in under 3 years.
Founder and CEO of Oxford Space Systems, Mike Lawton, said: “I’m delighted about the excellent progress we’ve made since founding the business in September 2013. This has placed us in a good position to close our planned second round of funding which has included the Stephenson Fund. We’re very pleased to have secured investment from the fund, as in addition to the gravitas of an association with the Institution, we’re looking forward to mutually beneficial opportunities to attract young talent to world of mechanical engineering.”
Visit the
Oxford Space Systems website.
Oxsensis
Oxsensis harsh environment instrumentation enables performance enhancement in critical applications in Aerospace, Energy and Oil and Gas. With Oxsensis’ optical sensors, invisible light is sent down an optical fibre and reflected from a piece of nano-machined sapphire, which is positioned in an extreme sensing application such as the wall of a gas turbine combustion system. This light is unaffected by high temperature, and the sapphire crystal is very resilient to the hostile environment – with technical differentiators being high temperature capability (1000 °C), immunity from electromagnetic interference, multi-measure and sensing, intrinsically safe sensors, and the ability to deploy at kilometres' distance.
Oxsensis has developed partnerships with major industrial companies including GE Aviation and Parker Aerospace. The company is using its core intellectual property to build a portfolio of customers and products in the high performance instrumentation market. The company’s instrumentation is aimed at enabling tangible improvements in efficiency, emissions, and performance in energy intensive capital equipment such as aero-engines, power stations, and oil production systems.
CEO Ian Macafee said: “Investment by the Institution's Stephenson Fund is a major vote of confidence in our young and innovative company and we look forward to benefitting from the wide support and opportunities that the Institution brings.”
Visit the
Oxsensis website.
Tokamak Energy
Tokamak Energy aims to accelerate the development of fusion as a low carbon energy source. Tokamak Energy’s approach uses recent advances in high temperature superconductors and the inherent performance advantages of spherical tokamaks to deliver a faster, more economical means of achieving fusion power from compact modules. The solution is scalable and modules could be built in factories or shipyards for rapid deployment. Tokamak Energy was announced in August as a
Technology Pioneer 2015 by the World Economic Forum; further recognition that the company has an exciting plan to tackle a major challenge.
Dr David Kingham, Tokamak Energy’s CEO, said: “The investment by the Institution is worth much more than the money to us. It is a recognition that the development of fusion energy is an engineering challenge that can be tackled through rapid innovation in compact devices. The world needs a clean base-load energy solution that is abundant, safe and CO2-free. Fusion is one of the few options available and we believe it is critical to find the quickest, most cost effective and realistic pathway to fusion energy.”
Visit the
Tokamak Energy website.