Difference between revisions of "2014 S Workshop Topics"

• UML Diagramm (state 27.05.2104)
• Main features of this ADE Energy

This Energy ADE is "ENEV-conform" (ENEV = German thermal regulation). The present scope is only the calculation of space heating and cooling demand
Modelling decision: The thermal hull is modelled separately from the existing boundary surfaces of CityGML, so as to be fully independant of the CityGML LOD and be able to modell complex thermal hull (attic storey and cellar partly heated etc.) The data modell follows fully the required inputs from the ENEV algorithm (8 facade surface area for the orientations N, NE, E, SE etc...).

• Remarks of the audience:

Why do you not keep the full information concerning the boundary surface orientations?
Why should the ADE Energy be restricted to one German regulation?

• UML Diagramm (state 27.05.2104)
• Main features of this ADE Energy

This Energy ADE is designed first for steady state simulation (yearly, monthly balance) but may be extended for dynamical simulation (hourly time step). The present scope is only the calculation of space heating / cooling and domestic hot water demand
Modelling decision: The thermal shell/hull is integrated into the existing boundary surfaces of CityGML, with the introduction of new thermal parameters (thermalBoundarySurfaceAboveGround, thermalBoundarySurfaceUnderGround, sharedSurfaceArea etc.). The new object "BuildingUnit" is introduced as reference simulation object. it can be either CityGML Building, or CityGML BuildingPart, or possibly CityGML Room in the case of LOD4. The ADE Energy is connected to building libraries (construction, windows, usage etc...).

• Remarks of the audience:

Where do you store your simulation results or measured consumption data? Answer: in the EnergyUse class.
How does it work with the CityGML LOD1 which has no BoundarySurface? Answer: New Boundary Surface objects are created.

• calculation of all building energy demands (with physical and statistical models), energy generation and energy supply.
• Modelling of Building Physics, HVAC Systems inside the building (geometrical information not necessary), HVAC controls and set-points, Building usage and occupants (maybe later outsourced into a Building Occupant ADE).
• should allow a plurality of building simulation models adapted to city scale (steady state energy balance, simplified dynamical simulation etc.)
• In comparison with the BIM format IFC for example, the ADE Energy of CityGML should also be a BIM, whose specificity is to tackle city scale energy issued, considering not only the buildings but also energy infrastructure, streets, vegetations and other urban objects.

• For the modelling of urban energy network, it exists already specific data model of network simulation softwares and the ADE Utility network (which could be soome integrated into the CityGML 3.0). Then, no urban energy infrastructure modelling is necessary for the ADE Energy (which focus on Building energy) but the reference point (network substations and heat exchangers) linking to the networks.

• List of standard parameters (nominal power, efficiency, seasonal efficiency etc.) + generic parameters specific to the different models.

• No common answer for the moment. Should be tested.

• Group Building Physics and Materials : K-H Häfele, R. Kaden, M. Lauster, R. Nouvel

Synchronised with development of CityGML 3.0 on Materials.

• Group HVAC systems and urban energy infrastructure : R. Nouvel, E. Duminil, D. Monien, M. Lauster, D. Perez
• Group Building Occupant : R. Nouvel, E. Munoz, J-M Bahu

See also projects "extra-Energy" around. May lead to a "Building occupant ADE".

• Group Metadata and scenarios : D. Perez, R. Nouvel