Albizia lebbeck, Ficus racemosa
mixed with ghee removes hunger for a fortnight; ingestion of a dose of the scum prepared from the mixture of
, rhizome of
, roots of
Aconitum ferox, Cynodon dactylon
, milk, ghee and manda enables one to fast for a month; similarly one can go without food for a month by consuming one dose of the powder of
Phaseolus radiatus, Hordeum vulgare, Dolichos biflorus
and root of
mixed with milk and ghee (Sensarma, 1996; Viswanathan and Singh, 1996). World Health Organisation (WHO) estimates that 80% of the populations living in the developing countries rely almost exclusively on traditional medicine for their primary health care needs, and 85% people in third world use plants or their extracts as the active substances in health care system (Shome et al., 1996; Sheldon et al., 1998). Plants have been used as medicines since beginning of human civilization. There are written evidences of medicinal uses of plants in texts of the ancient Chinese, Indian and other civilizations. India has had a history of ancient traditional medicinal practice based mostly on Ayurveda, Siddha and Unani systems of medicine. Medicinal plants have always been the main constituents of the traditional medicine.
includes about 2000 drugs of natural origin almost all of which are derived from traditional system; out of these 400 are of mineral origin and the rest are of plant origin. Ayurveda is based on natural products of nearly 2,000 cultivated and wild plant species. The written records of Ayurveda like
Charaka Samhita, Shushruta
and others contain more than 8,000 herbal remedies. There are literally millions of plants, combinations, traditions and household remedies to treat varieties of diseases and to boost health (Pearce and Moran, 1994; Subrat et al., 2002). Traditional knowledge of plants for medicinal purposes was based on observations and personal experiences. This knowledge was handed down from one generation to next generations mostly by word of mouth. In most societies there are no written records of such knowledge. By 19
century active principles of medicinal plants were isolated based on such knowledge base and discovery of quinine from
bark was the first active principle isolated and characterized (Phillipson, 2001). Reserpine, a drug prescribed for hypertension, was isolated from the root of shrub
based on ethnobotanical knowledge. Neem tree (
STORM’s latest achievements, as well as other useful resources will be shared in this section.
STORM articles and papers
“Operational Demand Forecasting in District Heating Systems Using Ensebmles of Online Machine Learning Algorithms,” Energy Procedia, Volume 116, June 2017: p.208 – 216. (scientific paper)
“Status of the Horizon 2020 STORM Project,” Energy Procedia, Volume 116, June 2017: p. 170-179. (scientific paper)
“Operational demand forecasting in district heating systems using ensembles of online machine learning algorithms” Award-winner at the 15th International Symposium on District Heating and Cooling in Seoul, South Korea, September 2016. (scientific paper)
“Release the Energy” – NODA’s Patrick Isacson discusses the relationship between digitalisation and district heating and cooling systems, October 2016 (article in Horizon 2020 Projects: Portal magazine)
“Storm Project lands award at DHC symposium” – DHCNews.co.uk, November 2016
“STORM Generic Controller Spans the Generations“, December 2016 (Interview with STORM coordinator Johan Desmedt in EU Research magazine)
“STORM project wins award for research excellence at DHC2016” – BuildUp, December 2016
“The Future of District Heating and Cooling Networks – Intelligent Controllers Based on Machine Learning Algorithms,” HOT COOL magazine N. 1, 2017
“Digitalisation of DHC – Optimising a Demand Driven System,” EuroHeat&Power Magazine, English Edition, Vol 14 IV/2017
Project communication materials
Project public deliverables
- D1.1 Report on classification of DHC networks and control strategies
- D2.1 Simulation platform configuration
- D3.2 Controller framework compatibility report
- D3.3 STORM controller evaluation report
- D5.1 Final report on the performance of the STORM controller
- D6.2 Economic assessment of business models for DHC networks operators
- D6.4 Report on STORM international and local dissemination activities
- D6.5 Report on education modules for universities of applied science in Europe
- D6.6 Report on training courses for professionals (proceedings of 5 training seminars)
What is DH?
District heating (DH) is a system for distributing heat for both residential and commercial heating requirements (space heating, hot water). The fundamental idea is to either recycle surplus heat from other processes which would be wasted otherwise or to have centralized/decentralised heat generation units which can meet a certain heat demand. DH systems produce medium – steam, hot water or chilled water which are then distributed to end-users. As a result, end-users do not need heat generation units such as boilers or furnaces. Numerous benefits can be achieved by connecting both residential and commercial sectors to DH network such as improved energy efficiency, fuel flexibility, enhanced environmental protection, decreased costs and reliability.
Further information: District Energy Explained, Euroheat & Power
Delivering the Energy Transition: What Role for District Energy, ECOFYS study commissioned by Euroheat & Power, 2016
District Heating, Wikipedia
Different generations of DH systems
Over the last decades, DH systems have been developed by introducing new technologies and by increasing energy efficiency. These changes have had a wide range of consequences which resulted in four different generations of DH systems in terms of technology, heat distribution, medium, circulation systems etc. Starting from the 1st generation where the heat carrier was steam, the last, 4th generation of DH provides low temperature DH systems with water at 30-60°C, depending on requirements. Apart from the heat carrier, circulation systems have changed from steam pressure and central pumps only to more sophisticated central and decentralised pumps. Another important development can be found in substations and radiators (heat exchangers) where floor heating and low-temperature radiators will be used.
Further information: Project description Strategic Research Centre for 4th Generation District Heating Technologies and Systems (4DH), 2012
4th Generation District Heating (4GDH): Integrating smart thermal grids into future sustainable energy systems, Henrik Lund, Sven Werner, Robin Wiltshire, Svend Svendsen, Jan Eric Thorsen, Frede Hvelplund, Brian Vad Mathiesen, 2014
Technologies used in DH systems
There are various heat sources which can be used for generating heat in DH systems including combined heat and power (CHP) plants, heating plants which can use biomass or fossil fuels, geothermal heat, solar heat, heat pumps and heat-only boilers. It should be mentioned that these sources can be combined for more efficient DH systems such as combining CHP units with heat-only boilers or heat pumps. Another component of DH systems is, mainly thermal, energy storage, which is used for storing excess energy. For the STORM project, geothermal systems and heat-only boilers are deployed. When it comes to geothermal DH systems, heat is extracted from the ground by creating drilling wells which is then used for meeding space heating demand or hot water preparation. In a system like this, no fuel is required since extracted heat is applied for medium preparation. On the other hand, heat-only boilers need fuel for generating heat. However, with the development of this technology, high energy efficiency can be achieved in a sustainable way by using bioenergy.
Further information: Developing Geothermal District Heating in Europe, GeoDH project, 2014
Control, automation and monitoring in DH systems
An important segment of DH systems operation are control, automation and montoring withing the system for the most efficient working load. DH controlers and system can provide trouble-free and energy-efficient network operation. Control valves, actuators and sensors in combination with proper communication within the system can ensull that all requirements are met in the most efficient, cost-effective way as fast as possible. Moreover, with the development of technology, it is possible nowadays, with the sophisticated systems and forecasting, to predict heat demand to be met by DH system. By doing this, peaks and requirements can be predicted and modelled accordingly which results with great flexiblity, automation and control.
Further information:District Heating and Cooling – A Vision towards 2020 – 2030 – 2050, DHC+ Technology Platform, 2012
Smart Heat Grid – How Does it Work?, NODA Intelligent Systems
Smart District Heating and Cooling, Energy Research Knowledge Centre – SETIS, European Commission, 2014