Redefining hospitality through a culture of innovation, sustainability and embracing diversity, equality and inclusion

Background

Glen Mhor, a hospitality business based in Inverness, is committed to redefining hospitality by fostering a culture of sustainability, green energy innovation, improved mental health and wellbeing, and embracing diversity, equality, and inclusion.
In 2006, Jon and Victoria Erasmus bought the Glen Mhor Hotel, and have since expanded by purchasing neighbouring buildings converting them into hotel accommodation and apartments. They have also built a low carbon Brewery and Distillery within the grounds of the hotel.
In 2022, they opened their river water source energy centre to decarbonise the hotel’s heating and hot water system. Through the construction of groundwater boreholes and the use of water source heat pumps, there is only one building left to connect in 2024 to see the business entirely gas free. This water source energy centre is the first of its kind in Scotland.
Their mission is to provide an exceptional guest experience whilst leaving a positive impact on the planet and community.

Challenges

Jon and Victoria were keen to explore two distinct areas of their business which they recognised would require external expertise.
The first, to develop a robust, evidence-based methodology for assessing and monitoring the new water source energy centre. As this is the first of its kind there is no data available to study the usage and contrast of how this compares from the old gas systems.
The second challenge focussed on their workforce and the adoption and integration of new workforce processes and practices to enable inclusive workforce onboarding and practices to support neurodiverse staff.

Solution – energy centre

Interface connected Glen Mhor to the School of Engineering, Computing and the Built Environment at Glasgow Caledonian University (GCU) who have expertise in the area of energy management, carbon assessment and Life Cycle Assessment (LCA). Professor Jim Baird undertook a detailed assessment of the metered energy systems and costs to develop an economic model for the hotel. The system analysis will also determine the amount of carbon emissions saved through the implementation of the energy centre.
This project was funded through a Standard Innovation Voucher designed to support the development of a new product, process, or service for a company.

Solution – workforce

Interface identified expertise at Edinburgh College from lecturer LizAnn Francis and Student Services Officer Rachel Robinson. Through this partnership, Glen Mhor and Edinburgh College devised a new recruitment policy and inclusive job advert template – both of which prioritise inclusivity, offering a sensory-friendly experience from application to employment.
This project was funded through a Workplace Innovation Voucher designed to develop a company’s internal workforce, including new or enhanced workplace processes, innovative workplace practices, or innovative business expertise.

Business Benefits

• Sharing best practices and looking at ways to future proof and develop its green vision further is core to Glen Mhor’s mission.
• Following the project with GCU Glen Mhor fully realise the benefits of their energy centre investment and are well placed to promote the project as best practice to the wider Scottish community.
• They have safeguarded and created jobs, increased turnover and reduced costs.
• For their work with Edinburgh College, early benefits include tailored support for job applicants and improved staff retention using health passports.
• Looking ahead, societal impacts are expected to include a more inclusive work environment, increased job satisfaction, and meaningful employment for neurodivergent individuals and those facing mental health issues.

University and College Benefits

• The project has offered Edinburgh College a greater understanding of workplace requirements to support neurodivergent people, mental health and disability employment. The cross collaboration within the college between the commercial department and the college student services provided real insight and practical solutions to what is normally theoretical HR policy.
• For Glasgow Caledonian University, their project has provided an opportunity to gain insight into the economics of transitioning low carbon solutions for heating commercial properties. It is hoped that further analysis can take place as more data is collected from the new system.

The 50th anniversary of SPE Offshore Europe takes place between 5-8 September 2023 at the P&J Live Aberdeen, to secure sustainable and equitable energy for the next 50 years and beyond.

If you are ready to connect with the Offshore Energy industry, network with brands across the entire value chain to find the latest innovations and developments within the industry and discover cutting-edge insights and trends attend the SPE conference designed around the four key themes of Energy Security, Energy Transition, Innovative Technology and Future Talent.
Reconnect with the industry to explore the evolving nature of the energy industry.

To find out more and to register visit SPE Offshore Europe

The rECOver group focuses on identifying and developing robotics as a sustainable technology and their potential contribution to a more sustainable world while identifying and working to overcome the social and economic implications associated with their integration by closing the gap between domestic and international policymakers and industrial partners.

The rECOver group comprises of a unique combination of cross discipline researchers including scientists, lawyers, sociologists and engineers.

This ‘Collider Event’ at the National Robotarium in Edinburgh, will bring together these sectors into a multidisciplinary group of experts to engage in discussions that will identify and draw out key principles and issues that should be addressed when using robotics for sustainability and focus on questions such as:

•Robotics in a sustainable world: are they accelerating or hindering the objectives?

•Can the increased use of robotics for sustainable mining affect the critical material supply?

•How does the contribution of robotic technology affect the transition to a circular economy?

•How can potential negative socio-economic or political impacts of robotics use be mitigated?

Robotic technology is increasingly being used to drive us to a more sustainable world, for example, in the offshore wind sector. However, whether and how robotics themselves can be made more sustainable – socially and environmentally – is emerging as an issue of debate. The development and use of these robots require coherent interdisciplinary analysis suitable to understanding their potential socioeconomic and environmental downsides and to create better regulatory approaches to incentivize innovation while avoiding negative externalities.

Initially, rECOver is seeking to initiate conversation and collaboration among scientists, engineers, policymakers and social scientists to analyse the use of robotics in mineral acquisition for and recycling of sustainable or ‘green’ technologies by combining both techno-economic and socio-political analysis.

Background 

Ecomar Propulsion Ltd is based in Fareham on the South Coast of the UK and was first registered in 2019.  Ecomar Propulsion Ltd is involved in the research, development and production of high performance electric and hybrid hydrogen marine propulsion systems. 

Their team of highly skilled engineers and technical experts are working to reduce global emissions by creating high efficiency, high output marine engines and energy storage solutions. The company only works with fully clean electric systems to allow current vessel owners the opportunity to seamlessly transfer to clean marine or new build yards to offer electric vessel options. 

Ecomar Propulsion produces two products for clean marine vessels; outboard systems and inboard systems powered by battery and hydrogen with a company aspiration of removing 10 million tonnes of toxic exhaust fumes from the marine environment within 10 years. 

In 2021 the company increased its workforce to 8 staff and then to 12 by Jan 2023, with further expected growth.  The company has been recognized with several awards from the Maritime UK (Solent) Clean Marine Innovator and Maritime UK Diversity Champion Finalist 2022 through to SETSquared University Network Award for Environmental Impact 2022. 

The Challenge 

The business challenge for Ecomar Propulsion arose when their manufacturer of hydraulic rams in the Far East ceased supply of their products. This left a significant challenge for Ecomar Propulsion but also an opportunity for the company to look at developing their supply chain within the UK.  Another requirement was to ensure the materials being used are as environmentally sustainable as possible from a circular economy perspective. 

The Solution 

Scottish Enterprise introduced Ecomar Propulsion to NMIS, and as a result of their interest in developing a Scottish supply chain and bringing production to Scotland to overcome a global supply chain issue of electric outboard motors, they were eligible to apply for the Inward Investment Catalyst Fund to support activity.  The Inward Investment Catalyst Fund supports businesses not yet located in Scotland but seeking to establish stronger ties with academia here.  As well as funding the research and development it provides an opportunity for the company to establish relationships and give insight into other aspects of the Scottish landscape, such as further investment opportunities, supply chains and the skills base to strengthen the case for investing in Scotland. 

The teams at NMIS and University of Strathclyde developed their understanding of the design and manufacturing parameters to find replacement components that would be robust enough for the extreme demands of the marine environment.   Research and outreach were carried out with companies specializing in hydraulic production in Scotland.  Further discussions with selected companies are taking place to develop future alternatives to current suppliers in order to close the gap in the market and provide consistency of supply. 

The Next Steps 

This project has allowed Ecomar Propulsion to better understand the work of NMIS and the University of Strathclyde and how the skills of the teams can allow Ecomar to plan further growth in Scotland and engage with the wider available supply chain.  

Whilst an immediate supplier for marine hydraulic rams was not found, the team have introduced Ecomar Propulsion to several companies which they would not have met had they not taken part in this project. Through meeting senior members of the academic community, potential further opportunities have been identified to explore additional supply chain introductions and manufacturing routes in Scotland for Ecomar Propulsion’s full product range.  

Continued collaboration will be facilitated with the Head of Electrification Manufacturing Programmes at NMIS, and allow Ecomar Propulsion and NMIS to engage with Scottish Government and Scottish Enterprise in relation to future facility planning and supply chain partnerships. Additionally, opportunities will be aligned with the University of Strathclyde’s strategic direction in electrification manufacturing, notably in PEMD (power electronics, machines and drives) through DER-IC Scotland (Driving the Electric Revolution Industrialisation Centre), ensuring that expansion of capabilities is informed and driven by industry requirements. 

This project benefitted from the Scottish Inward Investment Catalyst Fund.  The Scottish Inward Investment Catalyst Fund launched by Interface and the Scottish Government promotes Scotland as a leading destination for inward investment and supports businesses not yet located in Scotland but seeking to establish stronger ties with academia here.  As well as funding research and development it provides an opportunity for the company to establish relationships and give insight into other aspects of the Scottish landscape, such as further investment opportunities, supply chains and the skills base to strengthen the case for investing in Scotland.

Evolve™ green energy technology is the first hydrogen electrolysis solution that can extract hydrogen from any natural water source including groundwater, tap water, and seawater, without desalination. 

Background 

Evolve Hydrogen Ltd wants to develop novel Proton Exchange Membrane (PEM) electrolyser technology to produce “green” hydrogen for use in industrial processes. This innovation unlike the traditional flat-stack designs of common PEM and alkaline electrolysers is designed in a honeycomb configuration with reactive parts placed in a concentric layout. The reactive parts are fabricated via injection moulding of a custom polymer which allow this technology to utilise impure water sources. 

The Challenge 

In developing their technology Evolve Hydrogen Ltd required a bespoke polymer material that enabled direct electrolysis of impure water sources, for example, seawater without the need for desalination. Optimisation of this material required a thorough understanding of its electrochemical performance and transport mechanism in various electrolysis environments. To improve the efficiencies of their prototypes this project required electrochemical engineering expertise to give a full characterisation of the polymer raw material and to recommend improvements in composition to advance Evolve™ technology. 

The Solution 

Evolve Hydrogen Ltd sought the expertise of the University of Strathclyde to perform this project based on recommendations by their technical advisors, two of whom were alumni of Strathclyde University.  Funding provided by Interface’s Inward Investment Catalyst Fund permitted the material characterization of the original polymer and suggestions for efficiency improvements to be carried out by the University of Strathclyde. 

Evolve Hydrogen Ltd provided samples and previous technical data to the University’s research staff, who performed the physical and electrochemical characterisation required as part of Evolve’s aim to achieve TRL 4 (Technology Readiness Level) status. Dr Edward Brightman and his team of electrochemical engineers used their expertise to create a specialised test cell. They also demonstrated the knowledge and the flexibility to adjust the research scope to address new questions of the materials being analysed.   

The work performed by the team of electrochemical engineers successfully characterised the original polymer material and suggested material and dimensional changes to improve the efficiencies of Evolve Hydrogen’s technology. 

The Future 

Evolve Hydrogen Ltd is committed to working with the University of Strathclyde because of their demonstrated level of professionalism, knowledge, creative thought, and the working relationship that has been established.  The University, the Power Networks Demonstration Centre (PNDC), and their industrial partners plan to collaborate for the testing of future prototypes and the fabrication of Minimal Viable Products for Evolve Hydrogen’s demonstrations.  They are seeking joint funding together to support an R&D pathway towards commercialisation in Scotland. 

The Benefits 

• The benefit of this project is to further the development of a novel green hydrogen production technology and to commercialise the technology in Scotland.  

• Decarbonization of transportation and many industrial processes with the integration of Evolve’s technology throughout Scotland.   

• Development of future strategic partnerships with key industry players in manufacturing, polymer production, and hydrogen end users such as offshore wind farms, utilities, and the transportation sector. 

• With the global demand for electrolysers far exceeding the supply Evolve see a tremendous growth in exports of their technology for Scotland starting in 2024. 

This project benefitted from the Scottish Inward Investment Catalyst Fund.  The Scottish Inward Investment Catalyst Fund launched by Interface and the Scottish Government promotes Scotland as a leading destination for inward investment and supports businesses not yet located in Scotland but seeking to establish stronger ties with academia here.  As well as funding research and development it provides an opportunity for the company to establish relationships and give insight into other aspects of the Scottish landscape, such as further investment opportunities, supply chains and the skills base to strengthen the case for investing in Scotland.

Subsea Expo is the world’s leading annual subsea exhibition and conference, held annually at P&J Live in Aberdeen, and also includes the industry’s prestigious awards ceremony, the Subsea Expo Awards.

The exhibition and conference are completely free to attend.

The exhibition is a quality-focused event showcasing the capabilities, innovations and cutting-edge technologies of the underwater sectors, with over 185 exhibitors and 6,500 delegates attending the latest show.

The conference runs multiple parallel sessions and attracts a broad range of experts to discuss the challenges facing the industry, new and transformational technologies, digitalisation, clean energy and the path to net zero, among other topics.

The Subsea Expo Awards dinner is an opportunity to join friends, colleagues and peers in celebrating the accomplishments of the industry’s standout individuals and companies and is held at P&J Live in Aberdeen.

Subsea Expo is organised by the Global Underwater Hub.

About Opportunity:

Tidal generators present a useful energy source, but suffer from the variation in power produced as the tides move in and out. The change in direction of flow also requires the generators to be bi-directional. A method is needed to store some of the energy produced during peak flows and released during low flows. A robust generating device is needed for this harsh environment, coupled with a low maintenance power storage device. The new St Andrews Combined Tidal Stream/Reversible Hydrogen System for Balanced Renewable Generation technology meets these requirements.By coupling the generators with a reversible fuel cell to store the spare energy as hydrogen gas, to be used later when needed, the reversible fuel cell should have good efficiency and reliability, as there are no pumps etc to use power or break down. It is also a simple, compact unit with the ability for easily extended capacity or power independently.

Key Benefits:

• Generates constant power from tidal source
• Small simple system incorporating a robust reversible fuel cell
• Simple and effective generation platform

Applications:

The system would be an ideal constant power supply for a remote community with a viable tidal source.

IP Status:

The reversible fuel cell system is protected by patents granted in the USA, Canada and Europe (see US 8,748,052). The research group continues to work in this area of fuel cell research and the University would like to speak to any company interested in the technology. Please complete the enquiry form below.

About Opportunity:

Glasgow Caledonian University has developed a novel optical concentrator capable of providing gain on two planes.  Such a concentrator can be used in a non-tracking wall mounted BIPV system. 

The concentrator provides higher optical gains than alternative optical elements, thereby reducing the amount of PV cell (and silicon) required.  Additionally, carefully selected FOVs (Field-of-Views) contribute to capture solar radiation throughout the day and all year round, removing the requirement for electromechanical tracking.

Further, the optical structure has been designed to take into account the fact that the sun’s path deviation from summer to winter is far less than the deviation from sunrise to sunset and the entrance aperture and concentrator profile have been optimsed to redirect sunlight to the exit aperture and to the PV material.

A concentrator PV-array based on this structure is also capable of providing ambient light to building interiors. 

The reduction of PV material can be particularly important in applications using Gallium Arsenide PV cells.

The optical element can be used not only for solar energy systems (solar PV and solar thermal), it also could be used to collect visible and infrared radiation in applications such as sensing and optical wireless communications.

Key Benefits:

• Reduction in cost of BIPV systems
• High optical gain
• High electrical power output
• Optimum collection of light at a variety of angles of incidence
• No electrical tracking required
• Provides illumination as well as energy generation
• Reduction in CO2 emissions

Applications:

• BIPV Systems
• Optical sensing
• Optical wireless communications
• Lighting

IP Status:

The technology is protected by a granted GB patent and international patent application (Priority date December 2011), now in Regional/National phase.

Small prototypes have been built and tested with extremely positive results. Larger prototype array units have now been completed and initial results have confirmed these impressive results with high levels of optical gain generated.

About Opportunity

The state of the art anode material used in Solid Oxide Fuel Cells is the Ni/YSZ ceramic-metal (cermet) composite (where YSZ = Y2O3/ZrO2) which has several difficulties in use. The anode is prepared as NiO/YSZ, and must be reduced to Ni/YSZ to work: this entails a large volumetric shrinkage, which can cause the cells to crack. Ni is a good catalyst for cracking hydrocarbon fuels, but tends to produce solid carbon, which then blocks the electrode, lowering performance and effective working life. The metallic Ni phase is also mobile and tends to sinter over time, again lowering performance.

Our technology overcomes these problems while achieving a comparable electrochemical performance, electrical and catalytic properties (significantly better when used with methane fuel). The new perovskite anode shows better tolerance to hydrocarbon fuels, without depositing carbon on the electrode. The perovskite anode can withstand more repeated cycling than a Ni/YSZ anode.

Key Benefits

• As effective as existing materials but without the problems such as cell cracking and reduced effective working life.
• Redox stable – no cracking on cycling.Highly tolerant of hydrocarbon fuels.
• Resistant to carbon deposition.No need for initial cell reduction.

Applications

• The perovskite anode can be used in any Solid Oxide Fuel Cell (SOFC) instead of Ni/YSZ, where redox stability or hydrocarbon use is needed. This covers most applications of SOFCs.
• The University would welcome enquiries from commercial parties interested in developing commercial applications of fuel cells and fuel cell materials.

IP Status

The University of St Andrews has granted patents in Japan, USA, Canada, China, Australia and Europe (GB, France, Denmark, Switzerland, Italy, Spain, Austria and Germany) and continues to perform R&D in advanced materials for fuel cells. The University is looking for a licensee to the patents and knowhow or a commercial collaborator to take it to market. Patent Numbers: PCT/GB2003/003344, Granted patents: US 7,504,172 , Europe 1532710. Additional information can be made available under a confidentiality agreement.