Tag Archives: cesi

Optimal planning and operation of multi-vector energy networks: A systematic review [1]

Energy Systems, integrated energy systems, multi-vector energy systems, Net Zero, , ,

Academics from the EPSRC National Centre for Energy Systems Integration (CESI) and the Supergen Energy Networks Hub Dr Hamid Hosseini, Dr Adib Allahham, Dr Sara Walker and Prof Phil Taylor recently published their journal paper in Elsevier’s prestigious journal Renewable & Sustainable Energy Reviews (impact factor 12.11).

About the author

Dr Hamid Hosseini joined Newcastle University in 2017 as a postdoctoral research associate to the EPSRC National Centre for Energy Systems Integration (CESI).  Since joining the team, Hamid has been actively involved in research looking at planning, optimisation and operational analysis of integrated multi-vector energy networks. He also collaborated with a multi-disciplinary team on the UKRI Research and Innovation Infrastructure (RII) roadmap project, advising UKRI on the current landscape and future roadmap of Energy RIIs. He has supported and collaborated with several CESI Flex Fund projects to investigate further various aspects of Energy Systems Integration (ESI). Moreover, he is working with the Executive Board of Northern Gas Networks to identify the potential energy systems challenges that could be investigated at the Customer Energy Village of the Integrated Transport Electricity Gas Research Laboratory (InTEGReL), through collaboration with a multi-disciplinary team of  energy experts in industry and academia.

Contact email: hamid.hosseini@ncl.ac.uk and profile details

The international aspiration to reach net zero carbon in energy systems by 2050 is growing. In the UK, the government has set a target of ‘Net Zero’ Greenhouse Gas (GHG) emissions by 2050 in order to reduce contribution to global warming [2]. This necessitates performing energy evaluation through a system-of-systems approach, in order to understand the intrinsic properties of the main layer/sections of the Integrated Energy Systems (IESs), from natural resources and distribution to the final energy user as well as the interactions and interdependencies within each layer/section [3].

This paper provides a systematic review of recent publications on simulation and analysis of integrated multi-vector energy networks (rather than energy hubs) and carries this out through the lens of the internationally accepted concept of the energy trilemma, i.e. Flexibility of Operation, Security of Supply and Affordability. The significant detail included in the paper and the link to the trilemma is required in order to identify gaps and directions for an appropriate future applied research for facilitating the path to a decarbonised economy.

A systematic literature review of nearly 200 published papers was carried out using keywords to analyse Integrated Energy Networks (IENs). The papers have a wide, international authorship (Figure 1), showing that the topic of energy networks analysis is an important topic for governments around the world, as this supports meeting carbon reduction targets. 

Figure 1 The number of reviewed papers from different countries, based on the affiliation of the first author

The reviewed papers were classified into three groups (i) Operational analysis (ii) Optimal dispatch and (iii) Optimal planning, focussing on energy networks including gas, electricity and district heating networks as well as their interactions and interdependencies.

Figure 2 The three subject groups of papers reviewed and their topics

A detailed evaluation of the energy trilemma was carried out for each of the three groups of papers.

The paper looks at key findings, provides insights for the energy research community towards pursuit of low carbon transition and makes recommendations for future research priorities including: (i) development and demonstration of cyber resilient smart energy management frameworks, (ii) ways to overcome organisational and regulatory barriers for future increased energy networks integration, (iii) uncertainty analysis of the future performance of IENs, (iv) potential economic value of energy systems integration and (v) deployment of smart multi-energy regions.

The full paper, will appear in the November 2020 issue of the Elsevier Journal, Renewable and Sustainable Energy Reviews, and is available to view online.

J.RSER

References:

[1] Hosseini, SHR, Allahham, A, Walker, SL, Taylor, P. (2020). Optimal planning and operation of multi-vector energy networks: A systematic review. Renewable and Sustainable Energy Reviews, 133. DOI: j.rseer.2020.110216

[2] Committee on Climate Change. Net Zero – the UK’s contribution to stopping global warming. 2019. accessed, https://www.theccc.org.uk/publication/ net-zero-the-uks-contribution-to-stopping-global-warming/. [Accessed 28 October 2019].

[3] Eusgel I, Nan C, Dietz S. System-of-systems approach for interdependent critical infrastructures. Reliab Eng Syst Saf 2011;96(6):679–86.

What will the UK’s future energy research and innovation infrastructure look like?

Energy Storage, Energy Systems, Heat, hydrogen, Impact, Net Zero, smartgrid, , , , ,

Dr Zoya Pourmirza and Dr Hamid Hosseini talk about their recent work as part of a team of energy experts from Newcastle University helping UK Research & Innovation with an analysis of the UK’s existing research landscape and future infrastructure requirements.

About the authors

Dr Zoya Pourmirza is a Research Associate in Newcastle University’s School of Engineering. She is involved in a number of research and teaching projects. Her principle research interests are in smart energy systems and information and communication technology (ICT) with particular emphasis on making the ICT infrastructure energy aware and cyber secure.

Contact details: zoya.pourmirza@ncl.ac.uk
Profile details

Dr Hamid Hosseini is a Research Associate in Newcastle University’s School of engineering. His principle research interest is in the simulation and analysis of energy system. In his work for the EPSRC National Centre for Energy Systems Integration (CESI), Hamid has been investigating the planning, optimisation and operation analysis of integrated energy networks.

Contact details: hamid.hosseini@ncl.ac.uk
Profile details

UK Research & Innovation (UKRI) has recently published two reports giving an analysis of the UK’s existing research landscape and identifying its future infrastructure requirements. These reports make recommendations across six broad research sectors key to ensuring the UK remains a global leader. These six research sectors are Biological Sciences, Health and Food; Physical Sciences and Engineering; Social Sciences, Arts and Humanities; Environmental Sciences; Computational and e-infrastructure and Energy.

As members of a multi-disciplinary team of EPSRC National Centre for Energy Systems Integration (CESI) academics and researchers from Newcastle University, we were commissioned by UKRI to consult with the energy community. The team, led by CESI’s Director, Professor Phil Taylor, worked with UKRI to draft reports detailing our findings and recommendations. In carrying out this work, we made a substantial contribution to the preparation of the energy sections of the UKRI Research Landscape and Research Infrastructure reports.

Consultation exercise

The consultation exercise had three main aims: to inform future research and innovation infrastructure priorities, to provide the groundwork to ensure the UK remains a global leader in research and innovation and to set out the essential infrastructure needed to reach this long-term vision.

The team consulted extensively with leading UK energy industry and academics with expertise across a wide range of sectors, including nuclear, renewables, hydrogen, conventional technologies and whole energy systems. The consultation process was also extensive, including two questionnaires, four facilitated workshops at different locations across the UK and over one hundred 1-1 interviews with experts.

Initial analysis and findings

Based on the feedback received in the first stage of the consultation process, we drafted an interim report to UKRI giving an initial analysis of the UK Energy research infrastructure and a description of the existing energy research landscape. This interim report was included as a chapter in the UKRI Infrastructure Roadmap report alongside chapters for each of other five key research sectors.

An important finding of our initial consultation exercise was that opportunities to grow future energy research and innovation infrastructure could be classified in seven key themes. These informed further rounds of consultation, and are listed in the UKRI initial analysis report as follows:

  • Whole energy systems, including energy demand and power distribution networks
  • Fuel cells and hydrogen
  • Energy storage
  • Renewable energy sources
  • Alternative fuels
  • Nuclear energy – fission and fusion
  • Carbon capture and storage
Energy sector themes overview [Graphic: UKRI]

Final reports

Following this second consultation exercise, we incorporated our findings into two detailed reports for UKRI on the existing energy research and innovation landscape and on the sector’s future infrastructure requirements. These formed the basis of the Energy sections in the two recently published UKRI reports:

These reports referenced key energy research undertaken across the UK, including research involving multi-disciplinary teams from Newcastle University such as CESI and the Active Building Centre (ABC).

Key findings and recommendations

As a result of the consultation exercise, we helped to develop a snapshot view of existing infrastructure of regional, national and international importance. We identified thirty-three dedicated energy infrastructures and help to write case studies of existing key energy research infrastructure which were published in the Landscape Analysis report.

In the report identifying opportunities to grow our capacity, our findings contributed to recommendations for how the energy themes can be progressed and identifying case studies for each. The published case studies include one of CESI’s research demonstrators, The Integrated Transport Electricity Gas Research Laboratory (InTEGReL), as infrastructure offering a whole-systems approach to the UK’s energy use. Newcastle University is working in partnership with Northern Gas Networks and Northern Powergrid to develop the site. Its aim will be to allow academia, industry and government to explore and test new technologies in the electricity, gas and transport sectors in one place, delivering a more secure, affordable, low-carbon energy system.

The Integrated Transport Electricity Gas Research Laboratory (InTEGReL) [Graphic:Northern Gas Networks]

Of particular relevance to CESI are the recommendations for the whole energy systems theme. These include a new interdisciplinary centre for excellence in energy analysis integration and a decarbonisation of heat demonstrator, both of which will make an important contribution to investigations into how we might achieve a net-zero energy future.

UKRI Research and Innovation Infrastructure: Energy
Project team

Professor Phil Taylor
Dr Damian Giaouris
Dr Sara Walker
Dr Zoya Pourmirza
Dr Hamid Hosseini
Laura Brown
Alison Norton

A Smart, Flexible Energy System – Dr David Greenwood

Energy Systems, , ,

About the AuthorDavid Greenwood

David Greenwood is a research associate at Newcastle University. His work focusses on solving problems caused by uncertainty and variability and harnessing the value of emerging flexible technologies. He has worked on projects funded by industry and the UK research councils, most recently the Smarter Network Storage project, run by UK Power Networks, and Energy Storage for Low Carbon Grids, funded by EPSRC.

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There has been a lot of interest in the UK about the need to transition to a smart flexible energy system, but what does this really mean, why do we need it, and how do we make it happen?
Flexibility refers to the ability to adapt to accommodate a change in circumstance; to bend without breaking. In an energy system, this means being ready to adjust the system operation in the face of increased uncertainty and reduced reliance on asset based redundancy. This is, in part, a response to the Energy Trilemma: the need for reliable, sustainable, affordable energy. Renewable energy has led to a less predictable supply, which necessitates either a high level of back-up from conventional generation, or a change in operation to allow us to absorb the variability.

Smart technology
Smart technology – which enables an increase in monitoring and control throughout the energy system – is key to enabling this flexibility. It is anticipated that we will increasingly move demand to meet supply; store energy and release it when it is needed; and reconfigure our networks to meet shifting requirements. Some suspect that smart technology could lead to increased vulnerability to cyber-attacks, but we believe that this increased awareness will allow us to better protect both new smart interventions, and vulnerabilities in the existing systems. One of the goals of CESI is to address these questions using a cyber-physical systems approach, and drawing on expertise from both Smart Grid and Computer Science experts.

Delivery
The technology to deliver a smart, flexible energy system largely exists; the key challenges now are to do with regulation and attitudes – encompassing everyone from industry stakeholders to domestic customers. We need to demonstrate that these approaches work in order to build confidence; we need to design regulations which are simple to apply, but allow flexibility to be evaluated in the same terms as conventional assets and approaches; we need to provide market arrangements which align the priorities of flexibility providers with the requirements of the system; and we need to engage customers, and show how they can benefit from providing flexibility.

As we stated in our response to the recent OFGEM call for evidence on this topic, a whole systems approach, with comprehensive demonstration, is required to build confidence in flexibility, and ensure that new methods can operate in synergy with one another. This approach is at the heart of CESI, and will allow us to provide that confidence, and help ensure that a smart, flexible energy system becomes a reality.

Contact Author

Dr David Greenwood
Research Associate
Electric Power Systems Research Group
School of Electrical and Electronic Engineering
Newcastle University

  • Email: david.greenwood@ncl.ac.uk
  • Telephone: 0191 2083409
  • http://www.ncl.ac.uk/eee/staff/profile/davidgreenwood.html#background