A system design for distributed energy generation in low temperature district heating (LTDH) networks
Jones, Sean; Gillott, Mark C.; Boukhanouf, Rabah; Walker, Gavin S.; Tunzi, Michele; Tetlow, David; Rodrigues, Lucélia Taranto; Sumner, M.
Mark C. Gillott
Rabah Boukhanouf email@example.com
Gavin S. Walker
Michele Tunzi firstname.lastname@example.org
David Tetlow email@example.com
Lucélia Taranto Rodrigues
M. Sumner firstname.lastname@example.org
Project SCENIC (Smart Controlled Energy Networks Integrated in Communities) involves connecting properties at the University of Nottingham’s Creative Energy Homes test site in a community scale, integrated heat and power network. Controls will be developed to allow for the most effective heat load allocation and power distribution scenarios. Furthermore, the system will develop the prosumer concept, where consumers are both buyers and sellers of energy in both heat and power systems.
This paper describes the initial phase of project SCENIC, achieving truly distributed generation within a heat network. The first of its kind, the system has a four pipe network configuration, consisting of a network flow loop to supply heat to homes, and a generation loop to collect energy from residential heating systems and supply it to a centralised thermal store.
To achieve the design, IES-VE steady state heat load and dynamic building modelling have been used. A pre-insulated Rehau Rauthermex piping diameter was sized using flow rate calculations. Pipe diameter is reduced in line with distance from the central pump and associated pressure losses. The diameter ranges from 40 to 25mm, with a heat loss as low as 7.0 W/m. In addition, flow rates will fluctuate below a maximum of 1.99 l/s.
Danfoss – 7 Series BS flatstations have been selected as the network-building heat interface units (HIU), to satisfy a calculated peak design heating loads of between 36.74 and 44.06 kW. Furthermore, to enable the prosumer concept and associated business models an adapted Danfoss Flatstations – 3 Series BS was selected to interface the distributed heat sources with the network.
This paper gives details of the novel system configuration and concept, energy flows, as well as calculation and modelling results for the heat network. A premise is given to maintaining low temperatures in the network to ensure system efficiency in line with the latest research thinking.
|Publication Date||Jul 18, 2017|
|Peer Reviewed||Peer Reviewed|
|APA6 Citation||Jones, S., Gillott, M. C., Boukhanouf, R., Walker, G. S., Tunzi, M., Tetlow, D., …Sumner, M. (2017). A system design for distributed energy generation in low temperature district heating (LTDH) networks|
|Keywords||Low temperature district heating, Smart heat networks, Distributed generation, Community energy|
|Related Public URLs||https://events.unibo.it/set2017|
|Copyright Statement||Copyright information regarding this work can be found at the following address: http://eprints.nottingh.../end_user_agreement.pdf|
SET2017 Full manuscript - Jones_131_Update_v2.pdf
Copyright information regarding this work can be found at the following address: http://eprints.nottingham.ac.uk/end_user_agreement.pdf
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