The HighEFF ambition is to be a platform for innovation for energy efficiency in the industry. Our main targets are to implement new and novel technology and knowledge in addition to value creation for the Norwegian industry through 15-20 new novel emerging concepts for energy and cost-efficient industry plants, heat recovery and utilization of surplus heat.
- Shape the innovation strategies and technology roadmaps for the industry to ensure a consistent direction towards national and international energy- and emission targets
- Communicate centre activities and results internally, to stakeholders, legislator and to the public.
- Enhance the knowledge on barriers and enablers for collective innovation processes.
- Allocate funding for at least one Novel Emerging Concept every year.
The recommendations pointed out by the expert group "FME Innovation Task Force" in 2018 are followed up by the HighEFF team. Special attention has been given to systematisation and registration of innovations as well as visibility of innovations internally and externally.
HighEFF have worked to facilitate for innovations through the following:
- Defining criteria for what an innovation is
- Dedicating an internal workshop to the topic innovation and presenting the actual innovations in HighEFF so far
- Systematic reporting of innovations through Annual Work Plans (AWP), status reporting and communication internally and externally
- Centre calls for Novel Emerging Concepts (NECs)
- As part of one dedicated research area in HighEFF, RA5 Society, covering innovation strategies and enablers and barriers for innovation in FME Centres and in the point of intersection between research/academia and industry.
In HighEFF the following criteria and definitions of innovation is agreed on:
Innovation can be a product, a technology, a component, a process or a sub-process, a model or sub-model, a concept, an experimental rig or a service that is new or significantly improved with respect to properties, technical specifications or ease of use. Innovation can also be new application of existing knowledge or commercialization of R&D results.
The innovation should be adopted by somebody or be ready for utilization provided that it is made probable that the innovation will be utilized within a limited timeframe.
When an HighEFF innovation is recorded the probability of success and impact is evaluated simuntaneously. If both criteria are high, the development of this innovation will continue with considerable effort.
Possible new ideas for innovations are examined by the management team yearly and updated status of already registered innovations and those under development are updated. At this point of date 36 innovations are registered in HighEFF. Specific innovations covering reduced emission and energy consumption in industry processes are summed up in "one-pagers". Illustrative presentations are easy to communicate and have a broad impact.
Novel Emerging Concepts
The internal annual funding of "Novel Emerging Concepts" (NEC) helps to strengthen innovation at the centre and allows for the development and testing of new ideas. The R&D partners can propose projects together with industry if possible, based on established criteria. 1.5 MNOK / year has been allocated for this scheme. So far, FME HighEFF has launched 3 new NEC projects.
To further emphasize innovation in HighEFF, and make room for new ideas, the yearly funding of Novel Emerging Concepts (NEC) will continue. In 2019 HighEFF funded two more NEC projects;
Using additive manufacturing for developing and testing novel heat exchanger concepts (HighEx)
In HighEx researchers develop and validate a new workflow that combines design and production modelling to allow accurate additive manufacture of advanced heat exchanger geometries. The outcome of HighEx will be to validate the new workflow by producing smaller samples and compare to the original design and production models. This work will provide input and inspiration for ongoing and future HighEFF activities on developing new heat exchanger concepts, as well as enabling manufacture of functional prototypes for lab-scale experimental validation.
Developing a tool that allow to consider complex trade-offs between energy savings and investment costs for energy storage (CETES).
In CETES researchers develop a methodology for finding the most optimal thermal energy storage technology for storing steam in process industry.
The ultimate goal is to promote the usage of fluctuating renewable energy sources in steam production by utilizing thermal storage in combination with a suitable power-to-heat technology (electric boiler or high-temperature heat pump). The storage technologies considered include steam accumulator, latent heat storage, molten salt storage, and concrete storage. The expected result from CETES is a methodology realized in Python for finding the optimal heat-to-power and storage technologies for a given application with specific steam demand and electricity prices.