Skip to main content
What do you want to do?
Foundation
Undergraduate
Postgraduate
International
Advanced Clinical Practice
Aerospace Engineering
Anthropology
Arts and Health
Biomedical Sciences
Business School
Chemical Engineering
Civil Engineering
Clinical Education
Computer Science
Creative Writing
Criminology
Design School
Digital Media
Economics and Finance
Education
Electronic and Electrical Engineering
English
Environmental Sciences
Film Studies
Games Design
Geography
Global Challenges
History
Journalism
Law
Life Sciences
Mathematics
Mechanical and Automotive Engineering
Media and Communications
Medicine
Musculoskeletal Ultrasound
Music
Nursing
Occupational Therapy
Physician Associate
Physiotherapy
Politics and International Relations
Psychology
Public Health and Health Promotion
Social Work
Sociology
Sport, Health and Exercise Sciences
Theatre
Campus life
Study support
Student Services
Professional Development Centre
Research
Research degrees
Our partners and networks
International students
Study abroad and exchange
International Summer Schools
Global alumni
Business advice and support
Higher and Degree Apprenticeships
Employing our students
Research and development
Facilities and services
Procurement services
Help for SMEs
Health and safety training
Business newsletter
Support Brunel
Contact us
News and Events
Brunel Alumni
Giving back to Brunel
Contact us
About
Colleges

Innovative solar heating for industrial processes

Application of Solar Thermal Energy to Processes (ASTEP) project aims to create a new innovative Solar Heating for Industrial Processes (SHIP) concept focused on overcoming the current limitations of these systems.

This solution is based on modular and flexible integration of two innovative designs for the solar collector (SunDial) and the Thermal Energy Storage (TES, based on Phase Change Materials, PCM) integrated via a control system which will allow flexible operation to maintain continuous service against the unpredictable nature of the solar source and partially during night operation.

Our project will demonstrate its capability to cover a substantial part of the heat demand of the process industry at temperatures above 150 ºC and for latitudes where current designs are not able to supply it. Its modularity and compactness will also enable easy installation and repair with reduced space requirements, while most of the components can be sourced locally.

The ASTEP`s process integration will allow full compatibility with the existing systems of potential end-users of SHIP. These aspects will provide a very competitive solution to substitute fossil fuel consumption. The developed solar concept will be tested at two industrial sites to prove the objective’s target of TRL5. Life Cycle Analysis will be included to validate and demonstrate the efficiency of the proposed technologies.

The first Industrial Site of the proposal is the world’s leading steel company, ArcelorMittal, with a heating demand above 220 ºC for a factory located at a latitude of 47.1 N (Iasi, Romania). The second site is the dairy company MANDREKAS, located at a latitude of 37.93 N (Corinth, Greece) with a heating demand for steam at 175 ºC and a cooling demand at 5 ºC. These test locations will validate the ASTEP solution for a substantial part of the potential requirements of industrial heating and cooling demand of the European Union (EU28), which is estimated at approximately 72 TWh per year.

Meet the Principal Investigator(s) for the project

Dr Valentina Stojceska
Dr Valentina Stojceska - PhD in Food Engineering – School of Biosystems Engineering, University College Dublin Postgraduate Certificate in Academic Practice (PGCAP) –Manchester Metropolitan University BSc in Biotechnology and Food Process Engineering - Faculty of Technology, St. Cyril and Methodius University of Skopje

Partnering with confidence

Organisations interested in our research can partner with us with confidence backed by an external and independent benchmark: The Knowledge Exchange Framework. Read more.

Project last modified 02/10/2023