Awesome
uesgraphs
uesgraphs is a Python package to describe Urban Energy Systems and manage their data in a Python graph structure. We extend the networkx Graph class and add basic methods to represent buildings and energy networks in the graph. uesgraphs can be used as a foundation to analyze energy network structures, evaluate district energy systems or generate simulation models.
uesgraphs is being developed at RWTH Aachen University, E.ON Energy Research Center, Institute for Energy Efficient Buildings and Indoor Climate.
Getting started
Install uesgraphs
uesgraphs relies on other packages to function correctly. On Windows, it may be
necessary to install shapely and pyproj before uesgraphs.
We recommend to download the .whl
files for installing shapely
and pyproj from the
Unofficial Windows Binaries for Python Extension Packages
for your system and python versions. Install both .whl files with
pip install <path/to/file.whl>
.
One way to get uesgraphs set up is to use a fresh Conda environment by following these steps:
- Install Miniconda or update your conda installation with
conda update conda
- Create a new environment with
conda create -n <nameOfEnvironment> python=3.6
- Activate the environment with
source activate <nameOfEnvironment>
on Linux oractivate <nameOfEnvironment>
on Windows - Clone uesgraphs with
git clone https://github.com/RWTH-EBC/uesgraphs.git
- Install uesgraphs with
pip install -e <path/to/your/uesgraphs>
- Verify your uesgraphs installation by running the automated tests. Go to your
uesgraphs top-level folder and type
py.test --mpl
Usage
You can assemble a graph of an urban energy system by adding buildings, network
nodes and edges to an UESGraph
object. The following code builds a heating
network from one building to another, connected via one network node:
import uesgraphs as ug
from shapely.geometry import Point
graph = ug.UESGraph()
supply = graph.add_building(
name='Supply',
position=Point(0, 10),
is_supply_heating=True,
)
demand = graph.add_building(
name='Building 1',
position=Point(50, 15),
)
heating_node = graph.add_network_node(
network_type='heating',
position=Point(30, 5),
)
graph.add_edge(supply, heating_node)
graph.add_edge(heating_node, demand)
You can go on to plot this energy system with
vis = ug.Visuals(graph)
vis.show_network(
show_plot=True,
scaling_factor=30,
)
Instead of building a graph from scratch, uesgraphs comes with an example containing all supported energy network types. You can create this example graph with
import uesgraphs as ug
from shapely.geometry import Point
graph = ug.simple_dhc_model()
graph = ug.add_more_networks(graph)
vis = ug.Visuals(example_district)
fig = vis.show_network(
show_plot=True,
scaling_factor=10,
)
This leads to the following plot:
You can extract single networks into their own subgraph with
heating_network_1 = graph.create_subgraphs('heating')['default']
In the example above, this extracts the first of the two heating networks shown in red:
You can use this graph framework to add data to the nodes and edges, e.g.
import uesgraphs as ug
from shapely.geometry import Point
graph = ug.UESGraph()
demand = graph.add_building(
name='Building 1',
position=Point(50, 15),
)
graph.nodes[demand]['heat_load_kW'] = 200
This can be used as a foundation to analyze networks or to generate models.
License
uesgraphs is released by RWTH Aachen University, E.ON Energy Research Center, Institute for Energy Efficient Buildings and Indoor Climate, under the MIT License.
Reference
To reference uesgraphs, please cite the following paper (doi 10.1016/j.energy.2016.04.023):
Marcus Fuchs, Jens Teichmann, Moritz Lauster, Peter Remmen, Rita Streblow, Dirk Müller: Workflow automation for combined modeling of buildings and district energy systems, Energy, Volume 117, Part 2, 2016, Pages 478-484.
The BibTex for this paper is:
@article{Fuchs2016,
doi = {10.1016/j.energy.2016.04.023},
url = {https://doi.org/10.1016/j.energy.2016.04.023},
year = {2016},
month = {dec},
publisher = {Elsevier {BV}},
volume = {117},
pages = {478--484},
author = {Marcus Fuchs and Jens Teichmann and Moritz Lauster and Peter Remmen and Rita Streblow and Dirk M\"{u}ller},
title = {Workflow automation for combined modeling of buildings and district energy systems},
journal = {Energy}
}
Acknowledgements
This work was supported by the Helmholtz Association under the Joint Initiative “Energy System 2050 – A Contribution of the Research Field Energy”.
Parts of uesgraphs have been developed within public funded projects and with financial support by BMWi (German Federal Ministry for Economic Affairs and Energy).
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